ARIB STD-T53-C.S0011-A Recommended Minimum Performance Standards for cdma2000 Spread Spectrum Mobile Stations Refer to "Industrial Property Rights (IPR)" in the preface of ARIB STD-T53 for Related Industrial Property Rights. Refer to "Notice" in the preface of ARIB STD-T53 for Copyrights.
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ARIB STD-T53-C.S0011-A
Recommended Minimum Performance Standards for cdma2000 Spread Spectrum
Mobile Stations
Refer to "Industrial Property Rights (IPR)" in the preface of ARIB STD-T53 for Related Industrial
Property Rights. Refer to "Notice" in the preface of ARIB STD-T53 for Copyrights.
Original Specification 1
This standard, ARIB-T53-C.S0011-A, was prepared by T53WG of Association of Radio 2
Industries and Businesses (ARIB) based upon the 3GPP2 specification, C.S0011-A v2.0. 3
4
Modification to the original specification 5
None. 6
7
Notes 8
1. This standard is only applied to the Band Class 3 operation while other band operations have 9
been specified. 10
2. This standard is only applied with spreading rate 1 operation while the other spreading rate 11
operation has been specified. 12
3. It’s recommended that the following erratum be adopted for this ARIB standard. The erratum 13
applies to Table 4.5.1.3.1-3, page 4-56. This correction will be incorporated into the next 14
revision of the corresponding specification in 3GPP2 TSG-C. 15
Table 4.5.1.3.1-3. Additional Band Class 3 Transmitter Spurious Emission Limits 16
More stringent of -60 dBc / 30 kHz and 2.5µW (-26 dBm) / 30 kHz;
25µW (-16 dBm) / 30 kHz; Pout ≤ 30 dBm
< 885 MHz and
> 958 MHz
-16 dBm / 1 MHz; Pout ≤ 44 dBm
More stringent of -60 dBc / 1 MHz and 13 dBm / 1 MHz; Pout > 44 dBm
The lower and upper limits of the frequency measurement are currently 10 MHz and 3 GHz in Japan radio measurement documents.
17
3GPP2 TSG-C Closing Plenary
Date: March 30, 2001
Recommended Minimum Performance Standards for cdma2000 Spread Spectrum Mobile Stations
Release A
COPYRIGHT
3GPP2 and its Organizational Partners claim copyright in this document and individual Organizational Partners may copyright and issue documents or standards
publications in individual Organizational Partner's name based on this document. Requests for reproduction of this document should be directed to the 3GPP2
Secretariat at [email protected]. Requests to reproduce individual OrganizationaPartner's documents should be directed to that Organizational Partner. See
Table A.2.11.2-4 Minimum Standards for Radio Configuration 5 Forward 35
Supplemental Channel (100% Frame Activity) with Space Time Spreading ............A-139 36
Table A.2.12.1-1. Test Parameters for Demodulation of Power Control Subchannel 37
during Reverse Pilot Channel Gating ....................................................................A-139 38
3GPP2 C.S0011-A Ballot Resolution Version
TABLES
xxxiv
Table A.2.13.1-1. Test Parameters for Demodulation of Power Control Subchannel 1
during Reverse Fundamental Channel Gating ...................................................... A-140 2
3
3GPP2 C.S0011-A Ballot Resolution Version
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NOTES 1
1. Base station refers to the functions performed on the land side, which are 2
typically distributed among a cell, a sector of a cell, and a mobile communications 3
switching center. 4
2. This standard uses the following verbal forms: Shall and shall not identify 5
requirements to be followed strictly to conform to the standard and from which no 6
deviation is permitted. Should and should not indicate that one of several 7
possibilities is recommended as particularly suitable, without mentioning or 8
excluding others; that a certain course of action is preferred but not necessarily 9
required; or that (in the negative form) a certain possibility or course of action is 10
discouraged but not prohibited. May and need not indicate a course of action 11
permissible within the limits of the standard. Can and cannot are used for 12
statements of possibility and capability, whether material, physical, or causal. 13
3. Unless indicated otherwise, this document presents numbers in decimal form. 14
Binary numbers are distinguished in the text by the use of single quotation marks. 15
4. Those wishing to deploy systems compliant with this standard should also be 16
compliant with Parts 15, 22, 24, and 27 of [2] and with the applicable rules and 17
regulations of local administrations. 18
5. The following operators define mathematical operations: 19
× indicates multiplication. 20
/ indicates division. 21
+ indicates addition. 22
- indicates subtraction. 23
* indicates complex conjugation. 24
∈ indicates a member of the set. 25
x indicates the largest integer less than or equal to x: 1.1 = 1, 1.0 = 1. 26
|x| indicates the absolute value of x: |-17|=17, |17|=17. 27
6. All Radio Configuration 1 Eb/Nt requirements for Band Class 0 in this document 28
are based on measured data. All radio configuration Eb/Nt requirements for Band 29
Class 1 through Band Class 9 in this document are based on simulated data with 30
standard margins of 1.3 dB for static and 1.5 dB for fading channel cases. 31
Additional Forward Fundamental Channel rate determination margins of 0.2, 0.3, 32
and 0.4 dB are added for the 1/2, 1/4, and 1/8 rate cases, respectively. An 33
additional Forward Supplemental Channel margin of 0.2 dB is added for Îor/Ioc 34
equal to 6 and 8 dB cases. Unless specified otherwise, the Forward Traffic Channel 35
uses 20 ms long frame structures. 36
7. This Standard supports testing of mobile stations compliant with [4] and 37
subsequent revisions. 38
8. Tests in this revision reference the Universal Neighbor List Message and the 39
Universal Handoff Direction Message to maintain consistency with new tests which 40
3GPP2 C.S0011-A Ballot Resolution Version
xxxvi
require the extended capability of these messages. Where possible, the Neighbor List 1
Message, Extended Neighbor List Message, General Neighbor List Message, Extended 2
Handoff Direction Message, and the Universal Handoff Direction Message may be 3
used. 4
9. For the test parameters tables, Îor is specified in terms of power spectral density in 5
a Spreading Rate 1 bandwidth. For testing applicable to Spreading Rate 3, the total 6
received power in a Spreading Rate 3 bandwidth is effectively 5 dB higher. 7
10. Many tests in this revision specify using the Paging Channel for general test setup 8
requirements. If the mobile station does not support the Paging Channel, then the 9
Broadcast Control Channel and Forward Common Control Channel shall be used in 10
lieu of the Paging Channel. 11
12
13
3GPP2 C.S0011-A Ballot Resolution Version
xxxvii
NORMATIVE REFERENCES 1
The following standards contain provisions which, through reference in this text, constitute 2
provisions of this Standard. At the time of publication, the editions indicated were valid. All 3
standards are subject to revision, and parties to agreements based on this Standard are 4
encouraged to investigate the possibility of applying the most recent editions of the 5
standards indicated below. ANSI and TIA maintain registers of currently valid national 6
standards published by them. 7
8
1. ANSI C63.4-1992, American National Standard for Methods of Measurement of Radio-Noise Emissions from Low-Voltage Electrical and Electronic Equipment in the Range of 9 kHz to 40 GHz, July 1992.
2. CFR Title 47, Code of Federal Regulations, October 2000.
3. EIA/IS-19-B, Recommended Minimum Standards for 800-MHz Cellular Subscriber Units, June 1988.
4. 3GPP2 C.S0002-A-1, Physical Layer Standard for cdma2000 Spread Spectrum Systems, October 2000.
5. 3GPP2 C.S0004-A-1, Signaling Link Access Control (LAC) Standard for cdma2000 Spread Spectrum Systems, October 2000.
6. 3GPP2 C.S0005-A-1, Upper Layer (Layer 3) Signaling Standard for cdma2000 Spread Spectrum Systems, October 2000.
7. 3GPP2 C.S0010-A, Recommended Minimum Performance Standards for cdma2000 Spread Spectrum Base Stations, 2001.
8. 3GPP2 C.S0026, Test Data Service Option (TDSO) for cdma2000 Spread Spectrum Systems, 2001.
9. 3GPP2 C.S0025, Markov Service Option (MSO) for cdma2000 Spread Spectrum Systems, 2001.
10. 3GPP2 C.S0013-A, Loopback Service Options (LSO) for cdma2000 Spread Spectrum Systems, 2001.
9
10
3GPP2 C.S0011-A Ballot Resolution Version
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1
No text. 2
3GPP2 C.S0011-A Ballot Resolution Version
1-1
1 INTRODUCTION 1
1.1 Scope 2
This Standard details definitions, methods of measurement, and minimum performance 3
characteristics for Code Division Multiple Access (CDMA) mobile stations. This Standard 4
shares the purpose of [4] (and subsequent revision thereof) by ensuring that a mobile 5
station can obtain service in any cellular system that meets the compatibility requirements 6
of [4]. 7
Compatibility, as used in connection with this Standard and [4], is understood to mean that 8
any mobile station is able to place and receive calls in any CDMA system. Conversely, all 9
CDMA systems are able to place and receive calls with any CDMA mobile station supporting 10
operation in the same band. 11
Test methods are recommended in this document; however, methods other than those 12
recommended may suffice for the same purpose. 13
1.2 Terms and Definitions 14
Access Attempt. A sequence of one or more access probe sequences on the Access Channel 15
or Enhanced Access Channel containing the same message. See also Access Probe, Access 16
Probe Sequence, and Enhanced Access Probe. 17
Access Channel. A Reverse CDMA Channel used by mobile stations for communicating to 18
the base station. The Access Channel is used for short signaling message exchanges, such 19
as call originations, responses to pages, and registrations. The Access Channel is a slotted 20
random access channel. 21
Access Probe. One Access Channel transmission consisting of a preamble and a message. 22
The transmission is an integer number of frames in length, and transmits one Access 23
Channel message. See also Access Probe Sequence and Access Attempt. 24
Access Probe Sequence. A sequence of one or more access probes on the Access Channel 25
or Enhanced Access Channel. The same Access Channel or Enhanced Access Channel 26
message is transmitted in every access probe of an access attempt. See also Access Probe, 27
Enhanced Access Probe, and Access Attempt. 28
ACLR. Adjacent Channel Leakage power Ratio. 29
Active Frame. A frame that contains data and therefore is enabled in terms of traffic 30
power. 31
Additional Preamble. A preamble sent after the last fractional preamble on the Reverse 32
Pilot Channel prior to transmitting on the Enhanced Access Channel or the Reverse 33
Common Control Channel. 34
Adjacent Channel Leakage power Ratio. The ratio of the on-channel transmit power to the 35
power measured in one of the adjacent channels. 36
AWGN. Additive White Gaussian Noise. 37
3GPP2 C.S0011-A Ballot Resolution Version
1-2
Bad Frame. A frame classified with insufficient frame quality or for Radio Configuration 1 1
9600 bps primary traffic only, with bit errors. See also Good Frame. 2
Band Class. A set of frequency channels and a numbering scheme for these channels. 3
Base Station. A fixed station used for communicating with mobile stations. Depending 4
upon the context, the term base station may refer to a cell, a sector within a cell, an MSC, 5
or other part of the wireless system. 6
Basic Access Mode. A mode used on the Enhanced Access Channel where a mobile station 7
transmits an Enhanced Access Channel preamble and Enhanced Access data in a method 8
similar to that used on the Access Channel. 9
orc
IEBCCH . The ratio of the average transmit energy per PN chip for the Broadcast Control 10
Channel to the total transmit power spectral density. 11
bps. Bits per second. 12
Broadcast Control Channel (BCCH). A code channel in a Forward CDMA Channel used for 13
transmission of control information from a base station to a mobile station. 14
BCCH_Chip_Bit. Number of PN chips per Broadcast Control Channel bit. For Spreading 15
Rate 1, BCCH_Chip_Bit is equal to 64 x v where v equals 1 when the data rate is 19200 16
bps, v equals 2 when the data rate is 9600 bps, and v equals 4 when the data rate is 4800 17
bps. For Spreading Rate 3, BCCH_Chip_Bit is equal to 192 x v where v equals 1 when the 18
data rate is 19200 bps, v equals 2 when the data rate is 9600 bps, and v equals 4 when the 19
data rate is 4800 bps. 20
CACH_Chip_Bit. Number of PN chips per Common Assignment Channel bit. For Spreading 21
Rate 1, CACH_Chip_Bit is equal to 128 for 9600 bps. For Spreading Rate 3, CACH_Chip_Bit 22
is equal to 384 for 9600 bps. 23
orc
IECACH . The ratio of the average transmit energy per PN chip for the Forward Common 24
Assignment Channel to the total transmit power spectral density. 25
Candidate Frequency. The frequency for which the base station specifies a search set, 26
when searching on other frequencies while performing mobile-assisted handoffs. 27
CDMA. See Code Division Multiple Access. 28
CDMA Channel. The set of channels transmitted between the base station and the mobile 29
stations within a given CDMA frequency assignment. See also Forward CDMA Channel and 30
Reverse CDMA Channel. 31
CDMA Channel Number. An 11-bit number corresponding to the center of the CDMA 32
frequency assignment. 33
CDMA Frequency Assignment. A 1.23 MHz segment of spectrum. For Band Class 0, the 34
channel is centered on one of the 30 kHz channels. For band classes 1, 4, 6, 8, 7, 8 and 9, 35
the channel is centered on one of the 50 kHz channels. For band classes 2 and 3, the 36
channel is centered on one of the 25 kHz channels. For Band Class 5, the channel is 37
centered on one of the 20 or 25 kHz channels. 38
3GPP2 C.S0011-A Ballot Resolution Version
1-3
CDMA Preferred Set. The set of CDMA channel numbers in a CDMA system corresponding 1
to frequency assignments that a mobile station will normally search to acquire a CDMA 2
Pilot Channel. 3
Chip Rate. Equivalent to the spreading rate of the channel. It is either 1.2288 Mcps or 4
3.6864 Mcps. 5
Code Channel. A subchannel of a Forward CDMA Channel or Reverse CDMA Channel. 6
Each subchannel uses an orthogonal Walsh function or quasi-orthogonal function. 7
Code Division Multiple Access (CDMA). A technique for spread-spectrum multiple-access 8
digital communications that creates channels through the use of unique code sequences. 9
Common Assignment Channel (CACH). A forward common channel used by the base 10
station to acknowledge a mobile station accessing the Enhanced Access Channel, and in 11
the case of Reservation Access Mode, to transmit the address of a Reverse Common Control 12
Channel and associated Common Power Control Subchannel. 13
Common Power Control Channel (CPCCH). A forward common channel which transmits 14
power control bits (i.e., common power control subchannels) to multiple mobile stations. 15
The Common Power Control Channel is used by mobile stations operating in the 16
Reservation Access Mode. 17
Common Power Control Subchannel. A subchannel on the Common Power Control 18
Channel used by the base station to control the power of a mobile station when operating 19
on the Enhanced Access Channel or when operating in the Reservation Access Mode on the 20
Reverse Common Control Channel. 21
Continuous Transmission. A mode of operation in which Discontinuous Transmission is 22
not permitted. 23
Convolutional Code. A type of error-correcting code. A code symbol can be considered as 24
the convolution of the input data sequence with the impulse response of a generator 25
function. 26
orc
IE CPCCH . The ratio of the average transmit energy per PN chip for the Forward 27
Common Power Control Channel to the total transmit power spectral density. 28
CRC. See Cyclic Redundancy Code. 29
Cyclic Redundancy Code (CRC). A class of linear error detecting codes which generate 30
parity check bits by finding the remainder of a polynomial division. See also Frame Quality 31
Indicator. 32
dBc. The ratio (in dB) of the sideband power of a signal, measured in a given bandwidth at 33
a given frequency offset from the center frequency of the same signal, to the total inband 34
power of the signal. For CDMA, the total inband power of the signal is measured in a 1.23 35
MHz bandwidth around the center frequency of the CDMA signal. 36
dBm. A measure of power expressed in terms of its ratio (in dB) to one milliwatt. 37
dBm/Hz. A measure of power spectral density. The ratio, dBm/Hz, is the power in one 38
Hertz of bandwidth, where power is expressed in units of dBm. 39
3GPP2 C.S0011-A Ballot Resolution Version
1-4
Discontinuous Transmission (DTX). A mode of operation in which a base station or a 1
mobile station switches its transmitter or a particular code channel on and off 2
autonomously. For the case of DTX operation on the Forward Dedicated Control Channel, 3
the Forward Power Control Subchannel is still transmitted. 4
dBW. A measure of power expressed in terms of its ratio (in dB) to one watt. 5
Eb. Average energy of an information bit at the mobile station antenna connector. 6
tb
NE . The ratio in dB of the combined received energy per bit to the effective noise power 7
spectral density at the mobile station antenna connector (see 1.4). 8
Ec. Average energy accumulated over one PN chip period (Ec). 9
orc
IE . The ratio in dB between the energy accumulated over one PN chip period (Ec) to the 10
total transmit power spectral density. 11
Effective Isotropic Radiated Power (EIRP). The product of the power supplied to the 12
antenna and the antenna gain in a direction relative to an isotropic antenna. 13
Effective Radiated Power (ERP). The product of the power supplied to the antenna and 14
the antenna gain relative to a half-wave dipole in a given direction. 15
EIB. See Erasure Indicator Bit. 16
EIRP. See Effective Isotropic Radiated Power. 17
Enhanced Access Channel (EACH). A reverse channel used by the mobile for 18
communicating to the base station. The Enhanced Access Channel operates in the Basic 19
Access Mode, Power Controlled Access Mode, and Reservation Access Mode. It is used for 20
transmission of short messages, such as signaling, MAC messages, response to pages, and 21
call originations. It can also be used to transmit moderate-sized data packets. 22
Enhanced Access Channel Preamble. A non-data bearing portion of the Enhanced Access 23
probe sent by the mobile station to assist the base station in initial acquisition and channel 24
estimation. 25
Enhanced Access Data. The data transmitted while in the Basic Access Mode or Power 26
Controlled Access Mode on the Enhanced Access Channel or while in the Reservation Mode 27
on a Reverse Common Control Channel. 28
Enhanced Access Header. A frame containing access origination information transmitted 29
immediately after the Enhanced Access Channel preamble while in the Power Controlled 30
Access Mode or Reservation Access Mode. 31
Enhanced Access Probe. One Enhanced Access Channel transmission consisting of an 32
Enhanced Access Channel preamble, optionally an Enhanced Access header, and optionally 33
Enhanced Access data. See also Enhanced Access Probe Sequence. 34
Enhanced Access Probe Sequence. A sequence of one or more Enhanced Access probes on 35
the Enhanced Access Channel. See also Enhanced Access Probe. 36
ERP. See Effective Radiated Power. 37
3GPP2 C.S0011-A Ballot Resolution Version
1-5
FCH_Chip_Bit. The number of PN chips per Fundamental Channel bit, equal to 1
1228800/rb for Spreading Rate 1 and 3686400/rb for Spreading Rate 3, where rb is the 2
data rate of the Fundamental Channel. 3
FCH Ec. Average energy per PN chip for one Forward Fundamental Channel. 4
FCH orc
IE . The ratio of the average transmit energy per PN chip for one Forward 5
Fundamental Channel to the total transmit power spectral density. 6
FCCCH_Chip_Bit. Number of PN chips per Forward Common Control Channel bit. For 7
Spreading Rate 1, FCCCH_Chip_Bit is equal to 32 x v where v equals 1 when the data rate 8
is 38400 bps, v equals 2 when the data rate is 19200 bps, and v equals 4 when the data 9
rate is 9600 bps. For Spreading Rate 3, FCCCH_Chip_Bit is equal to 96 x v where v equals 10
1 when the data rate is 38400 bps, v equals 2 when the data rate is 19200 bps, and v 11
equals 4 when the data rate is 9600 bps. 12
orc
IE FCCCH . The ratio of the average transmit energy per PN chip for the Forward 13
Common Control Channel to the total transmit power spectral density. 14
FER. Frame Error Rate of Forward Traffic Channel. The value of FER may be estimated by 15
using Service Option 2, 9, 30, 31, 32, 54 or 55. 16
Forward CDMA Channel. A CDMA Channel from a base station to mobile stations. The 17
Forward CDMA Channel contains one or more code channels that are transmitted on a 18
CDMA frequency assignment using a particular pilot PN offset. 19
Forward Common Control Channel (FCCCH). A control channel used for the transmission 20
of digital control information from a base station to one or more mobile stations. 21
Forward Dedicated Control Channel (DCCH). A portion of a Radio Configuration 3 22
through 9 Forward Traffic Channel used for the transmission of higher-level data, control 23
information, and power control information from a base station to a mobile station. 24
Forward Fundamental Channel (FCH). A portion of a Forward Traffic Channel which 25
carries a combination of higher-level data and power control information. 26
Forward Power Control Subchannel. A subchannel on the Forward Fundamental Channel 27
or Forward Dedicated Control Channel used by the base station to control the power of a 28
mobile station when operating on the Reverse Traffic Channel. 29
Forward Supplemental Channel (SCH). A portion of a Radio Configuration 3 through 9 30
Forward Traffic Channel which operates in conjunction with a Forward Fundamental 31
Channel or a Forward Dedicated Control Channel in that Forward Traffic Channel to 32
provide higher data rate services, and on which higher-level data is transmitted. 33
Forward Supplemental Code Channel (SCCH). A portion of a Radio Configuration 1 and 2 34
Forward Traffic Channel which operates in conjunction with a Forward Fundamental 35
Channel in that Forward Traffic Channel, and (optionally) with other Forward Supplemental 36
Code Channels to provide higher data rate services, and on which higher-level data is 37
transmitted. 38
3GPP2 C.S0011-A Ballot Resolution Version
1-6
Forward Traffic Channel. One or more code channels used to transport user and signaling 1
traffic from the base station to the mobile station. See Forward Fundamental Channel, 2
Forward Dedicated Control Channel, Forward Supplemental Channel, and Forward 3
Supplemental Code Channel. 4
FPC_PRI_CHANs. Power Control Subchannel indicator set by the base station to indicate 5
whether the mobile station is to perform the primary inner loop estimation on the received 6
Forward Fundamental Channel or the Forward Dedicated Control Channel. 7
Frame. A basic timing interval in the system. For the Sync Channel, a frame is 26.666... 8
ms long. For the Access Channel, the Paging Channel, the Broadcast Control Channel, the 9
Forward Supplemental Code Channel, and the Reverse Supplemental Code Channel, a 10
frame is 20 ms long. For the Forward Supplemental Channel and the Reverse Supplemental 11
Channel, a frame is 20, 40, or 80 ms long. For the Enhanced Access Channel, the Forward 12
Common Control Channel, and the Reverse Common Control Channel, a frame is 5, 10, or 13
20 ms long. For the Forward Fundamental Channel, Forward Dedicated Control Channel, 14
Reverse Fundamental Channel, and Reverse Dedicated Control Channel, a frame is 5 or 20 15
ms long. For the Common Assignment Channel, a frame is 5 ms long. 16
Frame Activity. The ratio of the number of active frames to the total number of frames 17
during channel operation. 18
Frame Offset. A time skewing of Forward Traffic Channel or Reverse Traffic Channel 19
frames from System Time in integer multiples of 1.25 ms. 20
Frame Quality Indicator. The CRC check applied to 9.6 and 4.8 kbps Traffic Channel 21
frames of Radio Configuration 1, all Forward Traffic Channel frames for Radio 22
Configurations 2 through 9, all Reverse Traffic Channel frames for Radio Configurations 2 23
through 6, the Broadcast Control Channel, Common Assignment Channel, Enhanced 24
Access Channel, and the Reverse Common Control Channel. 25
GHz. Gigahertz (109 Hertz). 26
Good Frame. A frame not classified as a bad frame. See also Bad Frame. 27
Good Frames. Frames not classified as bad frames. See also Bad Frames. 28
Good Message. A received message is declared a good message if it is received with a 29
correct CRC. 30
Handoff. The act of transferring communication with a mobile station from one base 31
station to another. 32
Hard Handoff. A handoff characterized by a temporary disconnection of the Traffic 33
Channel. Hard handoffs occur when the mobile station is transferred between disjoint 34
Active Sets, the CDMA frequency assignment changes, the frame offset changes, or the 35
mobile station is directed from a CDMA Traffic Channel to an analog voice channel. See also 36
Soft Handoff. 37
HPSK. Hybrid phase shift keying. 38
I0. The total received power spectral density, including signal and interference, as 39
measured at the mobile station antenna connector. 40
3GPP2 C.S0011-A Ballot Resolution Version
1-7
Ioc. The power spectral density of a band-limited white noise source (simulating 1
interference from other cells) as measured at the mobile station antenna connector. 2
Ior. The total transmit power spectral density of the Forward CDMA Channel at the base 3
station antenna connector. 4
Îor. The received power spectral density of the Forward CDMA Channel as measured at the 5
mobile station antenna connector. 6
kHz. Kilohertz (103 Hertz). 7
Mcps. Megachips per second (106 chips per second). 8
Mean Input Power. The total received calorimetric power measured in a specified 9
bandwidth at the antenna connector, including all internal and external signal and noise 10
sources. 11
Mean Output Power. The total transmitted calorimetric power measured in a specified 12
bandwidth at the antenna connector when the transmitter is active. 13
Common Control Channel preamble, and Reverse Traffic Channel Preamble. 33
Primary Paging Channel. The default code channel (code channel 1) assigned for paging on 34
a CDMA Channel. 35
3GPP2 C.S0011-A Ballot Resolution Version
1-10
PS. Pilot Strength. Also see Pilot Ec/I0. 1
PUF. See Power Up Function. 2
PUF Probe. One or more consecutive frames on the Reverse Traffic Channel within which 3
the mobile station transmits the PUF pulse. 4
PUF Pulse. Portion of PUF probe which may be transmitted at elevated output power. 5
PUF Target Frequency. The CDMA frequency to which the base station directs a mobile 6
station for transmitting the PUF probe. 7
QIB. See Quality Indicator Bit. 8
QPSK. Quadrature phase shift keying. 9
Quality Indicator Bit (QIB). A bit used in the Radio Configurations 3, 4, 5, and 6 Reverse 10
Power Control Subchannel to indicate signal quality on the Forward Dedicated Control 11
Channel. When the Forward Fundamental Channel is present, this bit is set the same as 12
the Erasure Indicator Bits. 13
Quick Paging Channel (QPCH). An uncoded, spread, and On-Off-Keying (OOK) modulated 14
spread spectrum signal sent by a base station to inform mobile stations operating in the 15
slotted mode during the idle state whether to receive the Forward Common Control Channel 16
or the Paging Channel starting in the next Forward Common Control Channel or Paging 17
Channel frame. 18
QPCH_Chip_Bit. Number of PN chips per Quick Paging Channel bit. For Spreading Rate 1, 19
Quick Paging_Chip_Bit is equal to 256 x v where v equals 1 when the data rate is 4800 bps 20
and v equals 2 when the data rate is 2400 bps. For Spreading Rate 3, Quick 21
Paging_Chip_Bit is equal to 768 x v where v equals 1 when the data rate is 4800 bps and v 22
equals 2 when the data rate is 2400 bps. 23
orc
IE QPCH . The ratio of the average transmit energy per PN chip for the Quick Paging 24
Channel to the total transmit power spectral density. 25
Radio Configuration (RC). A set of Forward Traffic Channel and Reverse Traffic Channel 26
transmission formats that are characterized by physical layer parameters such as 27
transmission rates, modulation characteristics, and spreading rate. 28
RC. See Radio Configuration. 29
Reservation Access Mode. A mode used on the Enhanced Access Channel and Reverse 30
Common Control Channel where a mobile station transmits an Enhanced Access preamble 31
and an Enhanced Access header in the Enhanced Access probe. The Enhanced Access data 32
is transmitted on a Reverse Common Control Channel using closed loop power control. 33
Reverse CDMA Channel. The CDMA Channel from the mobile station to the base station. 34
From the base stations perspective, the Reverse CDMA Channel is the sum of all mobile 35
station transmissions on a CDMA frequency assignment. 36
3GPP2 C.S0011-A Ballot Resolution Version
1-11
Reverse Common Control Channel. A portion of a Reverse CDMA Channel used for the 1
transmission of digital control information from one or more mobile stations to a base 2
station. It can be power and may support soft handoff. 3
Reverse Dedicated Control Channel. A portion of a Radio Configuration 3 through 6 4
Reverse Traffic Channel used for the transmission of higher-level data and control 5
information from a mobile station to a base station. 6
Reverse Fundamental Channel. A portion of a Reverse Traffic Channel which carries 7
higher-level data and control information from a mobile station to a base station. 8
Reverse Pilot Channel. An unmodulated, direct-sequence spread spectrum signal 9
transmitted continuously by a CDMA mobile station. A reverse pilot channel provides a 10
phase reference for coherent demodulation and may provide a means for signal strength 11
measurement. 12
Reverse Power Control Subchannel. A subchannel on the Reverse Pilot Channel used by 13
the mobile station to control the power of a base station when operating on the Forward 14
Traffic Channel with Radio Configurations 3 through 9. 15
Reverse Supplemental Channel. A portion of a Radio Configuration 3 through 6 Reverse 16
Traffic Channel which operates in conjunction with the Reverse Fundamental Channel or 17
the Reverse Dedicated Control Channel in that Reverse Traffic Channel to provide higher 18
data rate services, and on which higher-level data is transmitted. 19
Reverse Traffic Channel. A traffic channel on which data and signaling are transmitted 20
from a mobile station to a base station. The Reverse Traffic Channel is composed of up to 21
one Reverse Dedicated Control Channel, up to one Reverse Fundamental Channel, zero to 22
two Reverse Supplemental Channels, and zero to seven Reverse Supplemental Code 23
Channels. 24
RF Carrier. A direct-sequence spread RF channel. For the Forward CDMA Channel, the 25
number of RF carriers is equal to the Spreading Rate; for the Reverse CDMA Channel, there 26
is one RF carrier. 27
RMS. Root of Mean Square. 28
SCCH_Chip_Bit. The number of PN chips per Supplemental Code Channel bit, equal to 29
1228800/rb for Spreading Rate 1 and 3686400/rb for Spreading Rate 3, where rb is the 30
data rate of the Supplemental Code Channel. 31
SCH_Chip_Bit. The number of PN chips per Supplemental Channel bit, equal to 32
1228800/rb for Spreading Rate 1 and 3686400/rb for Spreading Rate 3, where rb is the 33
data rate of the Supplemental Channel. 34
SCCH Ec. Average energy per PN chip for one Forward Supplemental Code Channel. 35
SCH Ec. Average energy per PN chip for one Forward Supplemental Channel. 36
SCCH orc
IE . The ratio of the average transmit energy per PN chip for one Forward 37
Supplemental Code Channel to the total transmit power spectral density. 38
3GPP2 C.S0011-A Ballot Resolution Version
1-12
SCH orc
IE . The ratio of the average transmit energy per PN chip for one Forward 1
Supplemental Channel to the total transmit power spectral density. 2
Service Option 2. Loopback service option for Radio Configuration 1 as specified in [10]. 3
Service Option 9. Loopback service option for Radio Configuration 2 as specified in [10]. 4
Service Option 30. Mobile station data loopback test mode for Multiplex Option 1 5
Supplemental Channel as specified in [10]. 6
Service Option 31. Mobile station data loopback test mode for Multiplex Option 2 7
Supplemental Channel as specified in [10]. 8
Service Option 32. Test data service option for Radio Configurations 3 through 6 on the 9
Reverse Traffic Channel and Radio Configurations 3 through 9 on the Forward Traffic 10
Channel as specified in [8]. 11
Service Option 54. Markov service option for Radio Configurations 1 through 6 on the 12
Reverse Traffic Channel and Radio Configurations 1 through 9 on the Forward Traffic 13
Channel as specified in [9]. 14
Service Option 55. Loopback service option for Radio Configurations 1 through 6 on the 15
Reverse Traffic Channel and Radio Configurations 1 through 9 on the Forward Traffic 16
Channel as specified in [10]. 17
Serving Frequency. The CDMA frequency on which a mobile station is currently 18
communicating with one or more base stations. 19
Slotted Mode. An operation mode of the mobile station in which the mobile station 20
monitors only selected slots on the Paging Channel. 21
Soft Handoff. A handoff occurring while the mobile station is in the Mobile Station Control 22
on the Traffic Channel State. This handoff is characterized by commencing communications 23
with a new base station on the same CDMA frequency assignment before terminating 24
communications with the old base station. See Hard Handoff. 25
Space Time Spreading (STS). A forward link transmission method which transmits all 26
forward link channel symbols on multiple antennas and spreads the symbols with 27
complementary Walsh or quasi-orthogonal functions. 28
Spreading Rate (SR). The PN chip rate of the Forward CDMA Channel or the Reverse 29
CDMA Channel, defined as a multiple of 1.2288 Mcps. 30
Spreading Rate 1. Spreading Rate 1 is often referred to as 1X. A Spreading Rate 1 31
Forward CDMA Channel uses a single direct-sequence spread carrier with a chip rate of 32
1.2288 Mcps. A Spreading Rate 1 Reverse CDMA Channel uses a single direct-sequence 33
spread carrier with a chip rate of 1.2288 Mcps. 34
Spreading Rate 3. Spreading Rate 3 is often referred to as 3X. A Spreading Rate 3 35
Forward CDMA Channel uses three direct-sequence spread carriers (see Multiple-Carrier 36
Forward Channel) each with a chip rate of 1.2288 Mcps. A Spreading Rate 3 Reverse CDMA 37
Channel uses a single direct-sequence spread carrier with a chip rate of 3.6864 Mcps. 38
3GPP2 C.S0011-A Ballot Resolution Version
1-13
SR. See Spreading Rate. 1
STS. See Space Time Spreading. 2
Symbol. See Code Symbol and Modulation Symbol. 3
Sync Channel. Code channel 32 in the Forward CDMA Channel, which transports the 4
synchronization message to the mobile station. 5
Sync_Chip_Bit. Number of PN chips per Sync Channel bit, equal to 1024. 6
Sync Ec. Average energy per PN chip for the Sync Channel. 7
orc
IESync . The ratio of the average transmit energy per PN chip for the Sync Channel to 8
the total transmit power spectral density. 9
TD. Transmit Diversity schemes, including OTD and STS. 10
Time Reference. A reference established by the mobile station that is synchronous with 11
the earliest arriving multipath component used for demodulation. 12
Traffic Channel. A communication path between a mobile station and a base station used 13
for user and signaling traffic. The term Traffic Channel implies a Forward Traffic Channel 14
and Reverse Traffic Channel pair. See also Forward Traffic Channel and Reverse Traffic 15
Channel. 16
Traffic_Chip_Bit. The number of PN chips per Traffic Channel bit, equal to 1228800/rb for 17
Spreading Rate 1 and 3686400/rb for Spreading Rate 3, where rb is the data rate. 18
Traffic Ec. Average energy per PN chip for the Forward Fundamental Channel. For the case 19
when the power control sub-channel is assumed to be transmitted at the same power level 20
that is used for the 9600 bps or 14400 bps data rate, the following equations apply: 21
For Radio Configuration 1, it is equal to v11
11+
× (total Forward Fundamental Channel 22
energy per PN chip), where v equals 1 for 9600 bps, v equals 2 for 4800 bps, v equals 4 for 23
2400 bps, and v equals 8 for 1200 bps traffic data rate. For Radio Configuration 2, it is 24
equal to v23
23+
× (total Forward Fundamental Channel energy per PN chip), where v equals 25
1 for 14400 bps, v equals 2 for 7200 bps, v equals 4 for 3600 bps, and v equals 8 for 1800 26
bps traffic data rate. The total Forward Fundamental Channel is comprised of traffic data 27
and a power control sub-channel. For Radio Configurations 3, 4, 6, and 7, it is equal to 28
v1111
+× (total Forward Traffic Channel energy per PN chip), where v equals 1 for 9600 bps, 29
v equals 2 for 4800 bps, v equals 4 for 2700 bps, and v equals 8 for 1500 bps traffic data 30
rate. For Radio Configurations 5, 8, and 9, it is equal to v11
11+
× (total Forward Traffic 31
Channel energy per PN chip), where v equals 1 for 14400 bps, v equals 2 for 7200 bps, v 32
equals 4 for 3600 bps, and v equals 8 for 1800 bps traffic data rate. The total Forward 33
Traffic Channel is comprised of traffic data and a power control sub-channel. 34
3GPP2 C.S0011-A Ballot Resolution Version
1-14
orc
IETraffic . The ratio of the average transmit energy per PN chip for the Forward Traffic 1
Channel to the total transmit power spectral density. 2
Turbo Code. A type of error-correcting code. A code symbol is based on the outputs of the 3
two recursive convolutional codes (constituent codes) of the Turbo code. 4
Valid Power Control Bit. A valid power control bit is sent on the Forward Traffic Channel 5
in the second power control group following the corresponding Reverse Traffic Channel 6
power control group which was not gated off and in which the signal strength was 7
estimated. See 3.1.3.1.10 of [4]. 8
Walsh Function. One of 2N time orthogonal binary functions (note that the functions are 9
orthogonal after mapping 0 to 1 and 1 to -1). 10
1.3 Test Modes 11
The Forward Traffic Channel is verified by invoking Fundamental Channel test modes, 12
Dedicated Control Channel test modes, Supplemental Code Channel test modes, and 13
Supplemental Channel test modes. The Reverse Traffic Channel is verified by invoking 14
Fundamental Channel test modes, Dedicated Control Channel test modes, and 15
Supplemental Channel test modes. Table 1.3-1 lists the nine test modes and the mapping 16
to radio configurations. 17
18
Table 1.3-1. Test Configuration Combinations 19
Test Mode Forward Traffic Channel Radio Configuration
Reverse Traffic Channel Radio Configuration
1 1 1
2 2 2
3 3 3
4 4 3
5 5 4
6 6 5
7 7 5
8 8 6
9 9 6
20
Fundamental Channel Test Mode 1 is entered by setting up a call using the Loopback 21
Service Option (Service Option 2 or 55) or the Markov Service Option (Service Option 54). 22
Fundamental Channel Test Mode 2 is entered by setting up a call using the Loopback 23
Service Option (Service Option 9 or 55) or the Markov Service Option (Service Option 54). 24
3GPP2 C.S0011-A Ballot Resolution Version
1-15
Fundamental Channel Test Modes 3 through 9 are entered by setting up a call using the 1
Loopback Service Option (Service Option 55), Markov Service Option (Service Option 54), or 2
Test Data Service Option (Service Option 32). 3
Dedicated Control Channel Test Modes 3 through 9 and Supplemental Channel Test Modes 4
3 through 9 are entered by setting up a call using the Test Data Service Option (Service 5
Option 32). 6
Supplemental Code Channel Test Mode 1 is entered by setting up a call using the Loopback 7
Service Option (Service Option 30). 8
Supplemental Code Channel Test Mode 2 is entered by setting up a call using the Loopback 9
Service Option (Service Option 31). 10
The mobile station shall support the Loopback Service Option if the mobile station supports 11
a Forward Fundamental Channel, Reverse Fundamental Channel or Forward Supplemental 12
Code Channel. The mobile station shall support the Test Data Service Option if it supports 13
a Forward Dedicated Control Channel, Reverse Dedicated Control Channel, Forward 14
Supplemental Channel, or Reverse Supplemental Channel. The mobile station may support 15
the Markov Service Option if the mobile station supports a Forward Fundamental Channel 16
or a Reverse Fundamental Channel. 17
1.4 CDMA Equations 18
The equations listed below describe the relationship between various test parameters under 19
different conditions. If the Paging Channel is not supported, the Forward Common Control 20
Channel may be substituted. 21
1.4.1 Transmit Power of the Base Station 22
orc
IEPilot
+ or
cI
E Sync +
or
cI
E QPCH +
orc
IEPaging
+ or
cI
E FCCCH + 23
or
cI
E BCCH +
or
cI
E CACH +
or
cI
E CPCCH +
orc
IE Traffic
+ or
cI
E ControlPower 24
+ or
cI
E SCCH +
or
cI
E SCH +
orc
IE OCNS
= 1 25
In the tests defined in this document, the following values are usually used: 26
orc
IEPilot
= -7 dB 27
orc
IE Sync
= -16 dB 28
orc
IEPaging
= -12 dB or or
cI
E FCCCH = -12 dB 29
3GPP2 C.S0011-A Ballot Resolution Version
1-16
Therefore, if or
cI
E Traffic = -16 dB at 9600 bps data rate, then 1
or
cI
E ControlPower = -26.41 dB 2
orc
IE OCNS
= -1.64 dB 3
Otherwise, if or
cI
E Traffic = -16 dB at 1200 bps data rate, then 4
orc
IE ControlPower
= -17.38 dB 5
orc
IE OCNS
= -1.75 dB 6
1.4.2 Received Signal Strength for Mobile Station Not in Handoff 7
Pilot 0c
IE
= 1
II
IEPilot
or
ocor
c
+ 8
1.4.2.1 Single-Path Case 9
Sync tb
NE
=
or
ocor
c
II
Bit_Chip_SyncI
E Sync×
10
QPCH tb
NE
=
or
ocor
c
II
Bit_Chip_QPCHI
E QPCH×
11
Paging tb
NE
=
or
ocor
c
II
Bit_Chip_PagingI
EPaging ×
12
3GPP2 C.S0011-A Ballot Resolution Version
1-17
BCCH tb
NE
=
or
ocor
c
II
Bit_Chip_BCCHI
E BCCH×
1
FCCCH tb
NE
=
or
ocor
c
II
Bit_Chip_FCCCHI
E FCCCH×
2
Traffic tb
NE
=
or
ocor
c
II
Bit_Chip_TrafficI
E Traffic×
3
SCCH tb
NE
=
or
ocor
c
II
Bit_Chip_SCCHI
E SCCH×
4
SCH tb
NE
=
or
ocor
c
II
Bit_Chip_SCHI
E SCH×
5
1.4.2.2 Two-Path Case 6
According to Channel Simulator Configuration 1, 2 and 5 (see 6.4.1.3), these two paths 7
have the same average power. 8
BCCH tb
NE
= or
cI
E BCCH × BCCH_Chip_Bit ×
21
II
1
or
oc + 9
Traffic tb
NE
= or
cI
E Traffic × Traffic_Chip_Bit ×
21
II
1
or
oc + 10
SCH tb
NE
= or
cI
E SCH × SCH_Chip_Bit ×
21
II
1
or
oc + 11
3GPP2 C.S0011-A Ballot Resolution Version
1-18
1.4.2.3 Three-Path Case 1
According to Channel Simulator Configuration 4 (see 6.4.1.3), the first two paths have the 2
same average power and the third path has half the average power of the first one. 3
BCCH tb
NE
= or
cI
E BCCH × BCCH_Chip_Bit × (2 ×
53
II
52
or
oc + +
54
II
51
or
oc +) 4
Traffic tb
NE
= or
cI
E Traffic × Traffic_Chip_Bit × (2 ×
53
II
52
or
oc + +
54
II
51
or
oc +) 5
SCH tb
NE
= or
cI
E SCH × SCH_Chip_Bit × (2 ×
53
II
52
or
oc + +
54
II
51
or
oc +) 6
1.4.3 Received Signal Strength for Mobile Station in Two-Way Handoff 7
According to Channel Simulator Configuration 2 (see 6.4.1.3), which is used in the tests of 8
the Forward Traffic Channel in two-way handoff, there are two paths from each cell and the 9
power received from each cell is Îor. 10
Pilot 0c
IE
(for each pilot) = 2
II
IEPilot
or
ocor
c
+ 11
Traffic tb
NE
= or
cI
E Traffic × Traffic_Chip_Bit ×
23
II
23
or
oc + 12
Generally, if the power received from cell 1 and cell 2 are Îor1 and Îor2, respectively, then 13
Pilot 0c
IE
1 = 1
II
II
IEPilot
1or2or
1oroc
1or
c
++ 14
3GPP2 C.S0011-A Ballot Resolution Version
1-19
Pilot 0c
IE
2 = 1
II
II
IEPilot
2or1or
2oroc
2or
c
++ 1
1.5 Tolerances 2
1.5.1 CDMA System Parameter Tolerances 3
CDMA parameters are specified in [4]. All parameters indicated in Sections 3 and 4 are 4
exact unless an explicit tolerance is stated. 5
1.5.2 Measurement Tolerances 6
Unless otherwise specified, a measurement tolerance, including the tolerance of the 7
measurement equipment, of ±10% is assumed. 8
Unless otherwise specified, the Îor /Ioc value shall be within ±0.1 dB of the value specified, 9
and the Ioc value shall be within ±5 dB of the value specified. 10
1.6 Test Requirements for Mobile Stations Supporting Analog Operation 11
Mobile stations supporting analog operation in the 800 MHz band shall conform to all 12
requirements in [3], with the exception of the test variations included in this section. 13
1.6.1 Modulated Tone Frequency 14
[3] states that a modulated tone frequency of 1000 Hz should be used in many tests. A 15
1004 Hz modulated tone frequency may be used in lieu of 1000 Hz. 16
17
3GPP2 C.S0011-A Ballot Resolution Version
1-20
1
No text. 2
3GPP2 C.S0011-A Ballot Resolution Version
2-1
2 STANDARD RADIATED EMISSIONS MEASUREMENT PROCEDURE 1
The measurement and calibration procedures described are intended to provide an overview 2
of radiated and conducted signal measurements. A detailed description of the required 3
measurement procedures is given in [1]. 4
2.1 Standard Radiation Test Site 5
The test site shall be on level ground that is of uniform electrical characteristics. The site 6
shall be clear of overhead wires and other metallic objects and shall be as free as possible 7
from undesired signals, such as ignition noise and other carriers. Reflecting objects, such 8
as rain gutters and power cables shall lie outside an ellipse measuring 60 meters on the 9
major axis by 52 meters on the minor axis for a 30-meter site, or an ellipse measuring 6 10
meters on the major axis by 5.2 meters on the minor axis for a 3-meter site. The equipment 11
under test shall be located at one focus of the ellipse and the measuring antenna at the 12
other focus. If desired, shelters may be provided at the test site to protect the equipment 13
and personnel. All such construction shall be of wood, plastic, or other non-metallic 14
material. All power, telephone, and control circuits to the site shall be buried at least 0.3 15
meter under ground. 16
A turntable, essentially flush with the ground, shall be provided that can be remotely 17
controlled. A platform 1.2 meters high shall be provided on this turntable to hold the 18
equipment under test. Any power and control cables that are used for this equipment 19
should extend down to the turntable, and any excess cabling should be coiled on the 20
turntable. 21
If the equipment to be tested is mounted in racks and is not easily removed for testing on 22
the above platform, then the manufacturer may elect to test the equipment when it is 23
mounted in its rack (or racks). In this case, the rack (or racks) may be placed directly on 24
the turntable. 25
If a transmitter with an external antenna connection is being tested, then the RF output of 26
this transmitter shall be terminated in a non-radiating load that is placed on the turntable. 27
A non-radiating load is used in lieu of an antenna to avoid interference with other radio 28
users. The RF cable to this load should be of minimum length. The transmitter shall be 29
tuned and adjusted to its rated output value before starting the tests. 30
In order to conduct unintentional radiator tests as specified in Part 15, subpart B of [2], the 31
radiation site must comply with Sections 5.4.6 through 5.5 of [1] as required by Part 2.948 32
of [2]. 33
2.2 Search Antenna 34
For narrow-band dipole adjustable search antennas, the dipole length shall be adjusted for 35
each measurement frequency. This length may be determined from a calibration ruler that 36
is normally supplied with the equipment. 37
The search antenna shall be mounted on a movable non-metallic horizontal boom that can 38
be raised or lowered on a wooden or other non-metallic pole. The cable connected to the 39
search antenna shall be at a right angle to the antenna. The cable shall be dressed at least 40
3GPP2 C.S0011-A Ballot Resolution Version
2-2
3 meters, either through or along the horizontal boom, in a direction away from the 1
equipment being measured. The search antenna cable may then be dropped from the end of 2
the horizontal boom to ground level for connection to the field-strength measuring 3
equipment. 4
The search antenna shall be capable of being rotated 90 degrees on the end of the 5
horizontal boom to allow measurement of both vertically and horizontally polarized signals. 6
When the antenna length of a vertically mounted antenna does not permit the horizontal 7
boom to be lowered to its minimum specified search range, adjust the minimum height of 8
the boom for 0.3 meter clearance between the end of the antenna and the ground. 9
2.3 Field-Strength Measurement 10
A field-strength meter shall be connected to a search antenna. The field-strength meter 11
shall have sufficient sensitivity and selectivity to measure signals over the required 12
frequency ranges at levels at least 10 dB below the levels specified in any document, 13
standard, or specification that references this measurement procedure. The calibration of 14
the measurement instruments (field-strength meter, antennas, etc.) shall be checked 15
frequently to ensure that their accuracy is in accordance with the current standards. Such 16
calibration checks shall be performed at least once per year. 17
2.4 Frequency Range of Measurements 18
When measuring radiated signals from transmitting equipment, the measurements shall be 19
made from the lowest radio frequency (but no lower than 25 MHz) generated in the 20
equipment to the tenth harmonic of the carrier, except for that region close to the carrier 21
equal to ±250% of the authorized bandwidth. 22
When measuring radiated signals from receiving equipment, the measurements shall be 23
made from 25 MHz to at least 6 GHz. 24
2.5 Test Ranges 25
2.5.1 30-Meter Test Range 26
Measurement of radiated signals shall be made at a point 30 meters from the center of the 27
turntable. The search antenna shall be raised and lowered from 1 to 4 meters in both 28
horizontally and vertically polarized orientations. 29
The field-strength measuring meter may be placed on a suitable table or tripod at the foot of 30
the mast. 31
When measuring radiated emissions from receivers, equipment that contains its own 32
receive antenna shall be tested with the antenna in place. Equipment that is connected to 33
an external receive antenna via a cable shall be tested without the antenna, and the receive 34
ports on the equipment under test shall be terminated in a 50Ω non-radiating resistive 35
load. 36
3GPP2 C.S0011-A Ballot Resolution Version
2-3
2.5.2 3-Meter Test Range 1
Measurement of radiated signals may be made at a point 3 meters from the center of the 2
turntable, provided the following three conditions can be met: 3
1. A ground screen that covers an elliptical area at least 6 meters on the major axis by 4
5.2 meters on the minor axis is used with the measuring antenna and turntable 5
mounted 3 meters apart. The measuring antenna and turntable shall lie on the 6
major axis and shall be equidistant from the minor axis of the elliptical area. 7
2. The maximum dimension of the equipment shall be 3 meters or less. When 8
measuring radiated signals from receivers, the maximum dimension shall include 9
the antenna if it is an integral part of the device. 10
3. The field-strength measuring equipment is either mounted below the ground level 11
at the test site or is located a sufficient distance away from the equipment being 12
tested and from the search antenna to prevent corruption of the measured data. 13
The search antenna shall be raised and lowered over a range from 1 to 4 meters in both 14
horizontally and vertically polarized orientations. When the search antenna is vertically 15
oriented, the minimum height of the center of the search antenna shall be defined by the 16
length of the lower half of the search antenna. 17
When measuring radiated emissions from receivers, equipment that contains its own 18
receive antenna shall be tested with the antenna in place. Equipment that is connected to 19
an external receive antenna via a cable shall be tested without the antenna, and the receive 20
ports on the equipment under test shall be terminated in a 50Ω non-radiating resistive 21
load. The 3-meter test range may be used for determining compliance with limits specified 22
at 30 meters (or other distances), provided that: 23
1. The ground reflection variations between the two distances have been calibrated for 24
the frequencies of interest at the test range, or 25
2. A 5 dB correction factor is added to the specified radiation limit(s) to allow for 26
average ground reflections. 27
Radiated field strength (volts/meter) varies inversely with distance, so that a measurement 28
made on the 3-meter test range divided by 10 gives the equivalent value that would be 29
measured on a 30-meter test range for the same EIRP (effective isotropic radiated power). 30
The 30-meter field strength in volts/meter can be calculated from the EIRP by using the 31
following formula: 32
µV/m @ 30 meters = 5773.5 × 10EIRP(dBm)/20 33
2.6 Radiated Signal Measurement Procedures 34
Radiated signals having significant levels shall be measured on the 30-meter or the 3-meter 35
range by using the following procedure: 36
1. For each observed radiated signal, raise and lower the search antenna to obtain a 37
maximum reading on the field-strength meter with the antenna horizontally 38
polarized. Then rotate the turntable to maximize the reading. Repeat this procedure 39
3GPP2 C.S0011-A Ballot Resolution Version
2-4
of raising and lowering the antenna and rotating the turntable until the highest 1
possible signal has been obtained. Record this maximum reading. 2
2. Repeat step 1 for each observed radiated signal with the antenna vertically 3
polarized. 4
3. Remove the equipment being tested and replace it with a half-wave antenna. The 5
center of the half-wave antenna should be at the same approximate location as the 6
center of the equipment being tested. 7
4. Feed the half-wave antenna replacing the equipment under test with a signal 8
generator connected to the antenna by means of a non-radiating cable. With the 9
antennas at both ends horizontally polarized and with the signal generator tuned to 10
the observed radiated signal, raise and lower the search antenna to obtain a 11
maximum reading on the field-strength measuring meter. Adjust the level of the 12
signal generator output until the previously recorded maximum reading for this set 13
of conditions is obtained. Record the signal generator power output. 14
5. Repeat step 4 above with both antennas vertically polarized. 15
6. Calculate the power into a reference ideal isotropic antenna by: 16
a. First reducing the readings obtained in steps 4 and 5 above by the power loss 17
in the cable between the generator and the source antenna, and 18
b. Then correcting for the gain of the source antenna used relative to an ideal 19
isotropic antenna. The reading thus obtained is the equivalent effective 20
isotropic radiated power (EIRP) level for the spurious signal being measured. 21
7. Repeat steps 1 through 6 above for all observed signals from the equipment being 22
tested. 23
24
3GPP2 C.S0011-A Ballot Resolution Version
3-1
3 CDMA RECEIVER MINIMUM STANDARDS 1
3.1 Frequency Coverage Requirements 2
The RF channel numbers and frequencies are given for base stations and mobile stations in 3
3.1.1 through 3.1.8. The mobile station receive CDMA frequency assignments are 4
associated on a one-to-one basis with the transmit CDMA frequency assignments. Each 5
CDMA frequency assignment shall be centered at one of the indicated frequencies. 6
3.1.1 Band Class 0 (800 MHz Band) 7
The channel spacing, CDMA channel designations, and transmit center frequencies for 8
Band Class 0 shall be as specified in Table 3.1.1-1. The Band Class 0 channel numbers are 9
shown in Tables 3.1.1-2 and 3.1.1-3. The preferred set of CDMA frequency assignments for 10
Band Class 0 is given in Table 3.1.1-4. 11
A mobile station supporting operation in Band Class 0 with Spreading Rate 1 shall support 12
CDMA operations on the valid and conditionally valid channel numbers shown in Table 13
3.1.1-21. A mobile station supporting operation in Band Class 0 with Spreading Rate 3 shall 14
support CDMA operations on the valid channel numbers shown in Table 3.1.1-31. Note that 15
certain channel assignments are not valid and others are conditionally valid. Transmission 16
on conditionally valid channels is permissible if the adjacent block is allocated to the same 17
licensee or if other valid authorization has been obtained. 18
19
Table 3.1.1-1. CDMA Channel Number to CDMA Frequency Assignment 20
Correspondence for Band Class 0 21
Transmitter CDMA Channel Number CDMA Frequency Assignment (MHz)
Mobile Station 1 ≤ N ≤ 799 0.030 N + 825.000
991 ≤ N ≤ 1023 0.030 (N-1023) + 825.000
Base Station 1 ≤ N ≤ 799 0.030 N + 870.000
991 ≤ N ≤ 1023 0.030 (N-1023) + 870.000
22
1Note that the Korean Cellular Band uses Band Subclass 1 and has additional valid channels that a Band Class 0 mobile station should support to permit roaming to Korea.
3GPP2 C.S0011-A Ballot Resolution Version
3-2
Table 3.1.1-2. CDMA Channel Numbers and Corresponding Frequencies for Band Class 1
0 and Spreading Rate 1 2
Transmit Frequency Band (MHz)
Band Subclass
System Designator
CDMA Channel Validity
CDMA Channel Number
Mobile Station Base Station
A" (1 MHz)
Not Valid Valid
991−1012 1013−1023
824.040−824.670 824.700−825.000
869.040−869.670 869.700−870.000
A (10 MHz)
Valid Not Valid
1−311 312−333
825.030−834.330 834.360−834.990
870.030−879.330 879.360−879.990
0 B (10 MHz)
Not Valid Valid
Not Valid
334−355 356−644 645−666
835.020−835.650 835.680−844.320 844.350−844.980
880.020−880.650 880.680−889.320 889.350−889.980
A' (1.5 MHz)
Not Valid Valid
Not Valid
667−688 689−694 695−716
845.010−845.640 845.670−845.820 845.850−846.480
890.010−890.640 890.670−890.820 890.850−891.480
B' (2.5 MHz)
Not Valid Valid
Not Valid
717−738 739−777 778−799
846.510−847.140 847.170−848.310 848.340−848.970
891.510−892.140 892.170−893.310 893.340−893.970
A" (1 MHz)
Not Valid Valid
991−1012 1013−1023
824.040−824.670 824.700−825.000
869.040−869.670 869.700−870.000
A (10 MHz)
Valid Not Valid
1−311 312−333
825.030−834.330 834.360−834.990
870.030−879.330 879.360−879.990
1 B (10 MHz)
Not Valid Valid
Not Valid
334−355 356−644 645−666
835.020−835.650 835.680−844.320 844.350−844.980
880.020−880.650 880.680−889.320 889.350−889.980
A' (1.5 MHz)
Not Valid Valid
667−688 689−716
845.010−845.640 845.670−846.480
890.010−890.640 890.670−891.480
A''' (2.5 MHz)
Valid Not Valid
717−779 780−799
846.510−848.370 848.400−848.970
891.510−893.370 893.400−893.970
3
3GPP2 C.S0011-A Ballot Resolution Version
3-3
Table 3.1.1-3. CDMA Channel Numbers and Corresponding Frequencies for Band Class 1
0 and Spreading Rate 3 2
Transmit Frequency Band (MHz)
Band Subclass
System Designator
CDMA Channel Validity
CDMA Channel Number
Mobile Station Base Station
A" (1 MHz)
Not Valid 991−1023 824.040−825.000 869.040−870.000
A (10 MHz)
Not Valid Valid
Not Valid
1−36 37−262 263−333
825.030−826.080 826.110−832.860 832.890−834.990
870.030−871.080871.110−877.860877.890−879.990
0 B (10 MHz)
Not Valid Valid
Not Valid
334−404 405−595 596−666
835.020−837.120 837.150−842.850 842.880−844.980
880.020−882.120882.150−887.850887.880−889.980
A' (1.5 MHz)
Not Valid 667−716 845.010−846.480 890.010−891.480
B' (2.5 MHz)
Not Valid 717−799 846.510−848.970 891.510−893.970
A" (1 MHz)
Not Valid 991−1023 824.040−825.000 869.040−870.000
A (10 MHz)
Not Valid Valid
Not Valid
1−36 37−262 263−333
825.030−826.080 826.110−832.860 832.890−834.990
870.030−871.080871.110−877.860877.890−879.990
1 B (10 MHz)
Not Valid Valid
Not Valid
334−403 404−595 596−666
835.020−837.090 837.120−842.850 842.880−844.980
880.020−882.090882.120−887.850887.880−889.980
A' (1.5 MHz)
Not Valid 667−716 845.010−846.480 890.010−891.480
A''' (2.5 MHz)
Not Valid Valid
Not Valid
717−737 738
739−799
846.510−847.110 847.140
847.170−848.970
891.510−892.110892.140
892.170−893.970
3
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Table 3.1.1-4. CDMA Preferred Set of Frequency Assignments for Band Class 0 1
Band Subclass
System Designator
Spreading Rate Preferred Set Channel Numbers
A 1 283 (Primary) and 691 (Secondary)
0 3 37, 78, 119, 160, 201, 2422
B 1 384 (Primary) and 777 (Secondary)
3 4252, 466, 507, 548, 589
A 1 779 (Primary) and 738 (Secondary)
1 3 37, 78, 119, 160, 201, 242, 7383
B 1 486 (Primary) and 568 (Secondary)
3 404, 445, 486, 527, 5683
2
3.1.2 Band Class 1 (1900 MHz Band) 3
The channel spacing, CDMA channel designations, and transmit center frequencies for 4
Band Class 1 shall be as specified in Table 3.1.2-1. The Band Class 1 channel numbers are 5
shown in Tables 3.1.2-2 and 3.1.2-3. The preferred set of CDMA frequency assignments for 6
Band Class 1 is given in Table 3.1.2-4. 7
A mobile station supporting operation in Band Class 1 with Spreading Rate 1 shall support 8
CDMA operations on the valid and conditionally valid channel numbers shown in Table 9
3.1.2-2. A mobile station supporting operation in Band Class 1 with Spreading Rate 3 shall 10
support CDMA operations on the valid channel numbers shown in Table 3.1.2-3. Note that 11
certain channel assignments are not valid and others are conditionally valid. Transmission 12
on conditionally valid channels is permissible if the adjacent block is allocated to the same 13
licensee or if other valid authorization has been obtained. 14
15
2 The use of preferred channel numbers 242 or 425 for Spreading Rate 3 ensures that overlaid multi-channel forward link systems with 1.23 MHz inter-channel spacing will contain a Spreading Rate 1 Forward CDMA Channel that aligns with one of the Spreading Rate 1 preferred channel numbers.
3 The use of preferred channel numbers 738, 445, 486, 527, or 568 for Spreading Rate 3 ensures that overlaid multi-channel forward link systems with 1.23 MHz inter-channel spacing will contain a Spreading Rate 1 Forward CDMA Channel that aligns with one of the Spreading Rate 1 preferred channel numbers.
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Table 3.1.2-1. CDMA Channel Number to CDMA Frequency Assignment 1
Correspondence for Band Class 1 2
Transmitter CDMA Channel Number
Center Frequency of CDMA Channel in MHz
Mobile Station 0 ≤ N ≤ 1199 1850.000 + 0.050 N
Base Station 0 ≤ N ≤ 1199 1930.000 + 0.050 N
3
Table 3.1.2-2. CDMA Channel Numbers and Corresponding Frequencies for 4
Valid refers to 600, 1000, and 1320 channel mobile stations. Valid-1000 refers to 1000 channel mobile stations. Valid-1320 refers to 1320 channel mobile stations.
6
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Table 3.1.3-3. CDMA Channel Numbers and Corresponding Frequencies for Band Class 1
Valid refers to 600, 1000, and 1320 channel mobile stations. Valid-1000 refers to 1000 channel mobile stations. Valid-1320 refers to 1320 channel mobile stations.
3
Table 3.1.3-4. CDMA Preferred Set of Frequency Assignments for Band Class 2 4
Block Designator
Spreading Rate Preferred Set Channel Numbers
A 1 79, 679, or 1365
3 Not specified
B 1 379, 947, or 1932
3 Not specified
5
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3.1.4 Band Class 3 (JTACS Band) 1
The channel spacing, CDMA channel designations, and transmit center frequencies for 2
Band Class 3 shall be as specified in Table 3.1.4-1. The Band Class 3 channel numbers are 3
shown in Table 3.1.4-2. The preferred set of CDMA frequency assignments for Band Class 3 4
is given in Table 3.1.4-3. 5
A mobile station supporting operation in Band Class 3 with Spreading Rate 1 shall support 6
CDMA operations on the valid and conditionally valid channel numbers shown in Table 7
3.1.4-2. Note that certain channel assignments are not valid and others are conditionally 8
valid. Transmission on conditionally valid channels is permissible if the adjacent block is 9
allocated to the same licensee or if other valid authorization has been obtained. 10
Spreading Rate 3 mobile station operation is not supported in Band Class 3. 11
12
Table 3.1.4-1. CDMA Channel Number to CDMA Frequency Assignment 13
Correspondence for Band Class 3 14
Transmitter CDMA Channel Number Center Frequency for CDMA Channel (MHz)
Mobile Station 1 ≤ N ≤ 799 0.0125 N + 915.000
801 ≤ N ≤ 1039 0.0125 (N 800) + 898.000
1041 ≤ N ≤ 1199 0.0125 (N 1040) + 887.000
1201 ≤ N ≤ 1600 0.0125 (N 1200) + 893.000
Base Station 1 ≤ N ≤ 799 0.0125 N + 860.000
801 ≤ N ≤ 1039 0.0125 (N 800) + 843.000
1041 ≤ N ≤ 1199 0.0125 (N 1040) + 832.000
1201 ≤ N ≤ 1600 0.0125 (N 1200) + 838.000
In this Table, only even-valued N values are valid.
15
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Table 3.1.4-2. CDMA Channel Numbers and Corresponding Frequencies for Band 1
Class 3 and Spreading Rate 1 2
Transmit Frequency Band (MHz)
System Designator
CDMA Channel Validity
CDMA Channel Number
Mobile Station Base Station
A1 (2 MHz)
Not Valid Valid
Not Valid
1041-1099
1100-1140
1141-1199
887.0125-887.7375
887.7500-888.2500
888.2625-888.9875
832.0125-832.7375
832.7500-833.2500
833.2625-833.9875
A3
(5 MHz)
Not Valid
Valid
Cond. Valid
1201-1259
1260-1540
1541-1600
893.0125-893.7375
893.7500-897.2500
897.2625-898.0000
838.0125-838.7375
838.7500-842.2500
842.2625-843.0000
A2 (3 MHz)
Cond. Valid Valid
Not Valid
801-859
860-980
981-1039
898.0125-898.7375
898.7500-900.2500
900.2625-900.9875
843.0125-843.7375
843.7500-845.2500
845.2625-845.9875
A (10 MHz)
Not Valid Valid
Not Valid
1-59
60-740
741-799
915.0125-915.7375
915.7500-924.2500
924.2625-924.9875
860.0125-860.7375
860.7500-869.2500
869.2625-869.9875
B Not specified Not specified Not specified Not specified
3
Table 3.1.4-3. CDMA Preferred Set of Frequency Assignments for Band Class 3 4
System Designator
Spreading Rate Preferred Set Channel Numbers
A 1 76 (Primary) and 872 (Secondary)
B 1 Not specified
5
3.1.5 Band Class 4 (Korean PCS Band) 6
The channel spacing, CDMA channel designations, and transmit center frequencies for 7
Band Class 4 shall be as specified in Table 3.1.5-1. The Band Class 4 channel numbers are 8
shown in Tables 3.1.5-2 and 3.1.5-3. The preferred set of CDMA frequency assignments for 9
Band Class 4 is given in Table 3.1.5-4. 10
A mobile station supporting operation in Band Class 4 with Spreading Rate 1 shall support 11
CDMA operations on the valid and conditionally valid channel numbers shown in Table 12
3.1.5-2. A mobile station supporting operation in Band Class 4 with Spreading Rate 3 shall 13
support CDMA operations on the valid channel numbers shown in Table 3.1.5-3. Note that 14
certain channel assignments are not valid and others are conditionally valid. Transmission 15
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on conditionally valid channels is permissible if the adjacent block is allocated to the same 1
licensee or if other valid authorization has been obtained. 2
3
Table 3.1.5-1. CDMA Channel Number to CDMA Frequency Assignment 4
Correspondence for Band Class 4 5
Transmitter CDMA Channel Number Center Frequency for CDMA Channel (MHz)
Mobile Station 0 ≤ N ≤ 599 0.050 N + 1750.000
Base Station 0 ≤ N ≤ 599 0.050 N + 1840.000
6
Table 3.1.5-2. CDMA Channel Numbers and Corresponding Frequencies for Band Class 7
The mobile station receiver shall be capable of detecting the signal defined in Section 3.1 of 2
[4]. 3
3.4.1 Demodulation of Forward Traffic Channel in Additive White Gaussian Noise 4
This test shall be performed for each band class supported by the mobile station. This test 5
shall be performed on the Forward Fundamental Channel, if the Forward Fundamental 6
Channel is supported by the mobile station. Otherwise, this test shall be performed on the 7
Forward Dedicated Control Channel. This test shall also be performed on the Forward 8
Supplemental Channel and the Forward Supplemental Code Channel if they are supported. 9
Forward Traffic Channel closed loop power control in the base station shall be disabled 10
during this test. 11
3.4.1.1 Definition 12
The performance of the demodulation of Forward Traffic Channel in an AWGN (no fading or 13
multipath) environment is determined by the frame error rate (FER). The FER is calculated 14
for each individual data rate. For Radio Configuration 2 Fundamental Channel, the 15
accuracy of the Erasure Indicator bits sent by the mobile station is verified in this test. 16
3.4.1.2 Method of Measurement 17
1. Connect the base station and an AWGN generator to the mobile station antenna 18
connector as shown in Figure 6.5.1-4. 19
2. For each band class that the mobile station supports, configure the mobile station 20
to operate in that band class and perform steps 3 through 11. 21
3. For each radio configuration supported on the Forward Fundamental Channel or 22
Forward Dedicated Control Channel, perform steps 4 through 7. 23
4. Set up a call using Fundamental Channel or Dedicated Control Channel test mode 24
(see 1.3) with frame activity equal to 100%. 25
5. Set the test parameters for each test as specified in Tables A.2.1.1-1 through 26
A.2.1.1-18. 27
6. Count, at the base station, the number of frames transmitted and the number of 28
good frames received at the mobile station. 29
7. For Radio Configuration 2, check the accuracy of the received Erasure Indicator 30
bits at the base station against the corresponding frames received at the mobile 31
station. 32
8. For each radio configuration supported on the Forward Supplemental Code 33
Channel or Forward Supplemental Channel, perform steps 9 through 11. 34
9. Set up a call using the appropriate Supplemental Code Channel Test Mode (see 1.3) 35
or Supplemental Channel Test Mode (see 1.3) with frame activity equal to 100%. 36
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10. Set the test parameters for each test as specified in Tables A.2.1.1-19 through 1
A.2.1.1-34. If the mobile station supports turbo coding on the Forward 2
Supplemental Channel, perform all the turbo coding tests for the supported 3
Forward Supplemental Channel data rates and only the convolutional coding test 4
for the maximum supported Forward Supplemental Channel data rate. If the mobile 5
station only supports convolutional coding on the Forward Supplemental Channel, 6
perform all the convolutional coding tests for the supported Forward Supplemental 7
Channel data rates. 8
11. Count, at the base station, the number of frames transmitted and the number of 9
good frames received at the mobile station on the Forward Supplemental Code 10
Channel or Forward Supplemental Channel. 11
3.4.1.3 Minimum Standard 12
The actual Eb/Nt used in each test shall be within ±0.2 dB of the value indicated in Tables 13
A.2.1.1-1 through A.2.1.1-34. 14
For Radio Configuration 2 Fundamental Channels, the mobile station shall set the Erasure 15
Indicator Bit to 1 in the second transmitted frame following the reception of any bad frame 16
on the Forward Fundamental Channel (see Section 2.2.2.2 of [4]). The value of the Erasure 17
Indicator bits corresponding to all other frames received at the mobile station shall be 0. 18
The FER for each test shall not exceed the piecewise linear FER curve specified by the 19
points in Tables A.2.1.2-1 through A.2.1.2-25 with 95% confidence (see 6.6). 20
3.4.2 Demodulation of Forward Traffic Channel in Multipath Fading Channel 21
This test shall be performed on the Forward Fundamental Channel with Radio 22
Configuration 1 or 2, if the Forward Fundamental Channel with Radio Configuration 1 or 2 23
is supported by the mobile station. 24
3.4.2.1 Definition 25
The performance of the demodulation of Forward Traffic Channel in multipath fading 26
channel is determined by the frame error rate (FER) or the error rate in each frame 27
category. The FER is calculated for each individual data rate. The following table 28
summarizes the fading tests to be performed: 29
30
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Case
Radio Configuration
Channel Simulator Configuration Number
1 1 1 (8 km/h, 2 paths)
2 1 3 (30 km/h, 1 path)
3 1 4 (100 km/h, 3 paths)
4 2 1 (8 km/h, 2 paths)
5 (band classes 0, 2, 3, 7 and 9 only)
2 3 (30 km/h, 1 path)
5 (Band Class 5 only) 2 3 (58 km/h, 1 path)
6 2 4 (100 km/h, 3 paths)
1
Cases 1 and 4 test the demodulation performance for the 8 km/h, two-path case by 2
checking the full rate FER. Cases 2 and 5 test the demodulation performance for the 30 3
km/h, single-path case by checking the FER at all four possible data rates. Cases 3 and 6 4
test the demodulation performance and the rate determination for the 100 km/h, three-5
path case by checking the FER and the error rate in each frame category. 6
3.4.2.2 Method of Measurement 7
1. Connect the base station and an AWGN generator to the mobile station antenna 8
connector as shown in Figure 6.5.1-1. 9
2. For each band class that the mobile station supports, configure the mobile station 10
to operate in that band class and perform steps 3 through 5. 11
3. If the mobile station supports demodulation of Radio Configurations 1 or 2, set up a 12
call using Fundamental Channel Test Mode 1 or 2 (see 1.3). 13
4. Set the test parameters for each test as specified in Tables A.2.2.1-1 through 14
A.2.2.1-9. 15
5. Count, at the base station, the number of frames transmitted and the number of 16
good frames received at the mobile station. For Cases 3 and 6, count, at the base 17
station, the number of frames received in each category at the mobile station. 18
3.4.2.3 Minimum Standard 19
A minimum confidence level of 95% shall be obtained for the following FER requirements 20
(see 6.6). 21
Case 1: 22
The actual Eb/Nt used in each test shall be within ±0.5 dB of the value indicated in Tables 23
A.2.2.1-1 and A.2.2.1-2. 24
The FER for each test at 9600 bps shall not exceed the piece-wise linear FER curve 25
specified by the points in Tables A.2.2.2-1 through A.2.2.2-3. 26
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Case 2: 1
The actual Eb/Nt used in each test shall be within ±0.5 dB of the value indicated in Tables 2
A.2.2.1-3 and A.2.2.1-4. 3
The FER for each test shall not exceed the piece-wise linear FER curve specified by the 4
points in Table A.2.2.2-4. 5
Case 3: 6
The actual Eb/Nt used shall be within ±0.2 dB of the value indicated in Table A.2.2.1-5. 7
The FER for each data rate shall not exceed the line specified by the points in Tables 8
A.2.2.2-5 and A.2.2.2-6. The error rate of each frame category should not exceed the 9
corresponding error rate value specified in Tables A.2.2.2-7 and A.2.2.2-8. 10
Case 4: 11
The actual Eb/Nt used in each test shall be within ±0.5 dB of the value indicated in Table 12
A.2.2.1-6. 13
The FER for each test at 14400 bps shall not exceed the piece-wise linear FER curve 14
specified by the points in Table A.2.2.2-9. 15
Case 5: 16
The actual Eb/Nt used in each Band Class 0 test shall be within ±0.5 dB of the value 17
indicated in Tables A.2.2.1-7 and A.2.2.1-8. 18
The FER for each test shall not exceed the piece-wise linear FER curve specified by the 19
points in Table A.2.2.2-10. 20
Case 6: 21
The actual Eb/Nt used in each test shall be within ±0.2 dB of the value indicated in Table 22
A.2.2.1-9. 23
The FER for each data rate shall not exceed the line specified by the points in Tables 24
A.2.2.2-11 and A.2.2.2-12. The error rate of each frame category should not exceed the 25
corresponding error rate value specified in Tables A.2.2.2-13 and A.2.2.2-14. 26
3.4.3 Demodulation of Forward Traffic Channel During Soft Handoff 27
This test shall be performed on the Forward Fundamental Channel with Radio 28
Configuration 1, if the Forward Fundamental Channel with Radio Configuration 1 is 29
supported by the mobile station. 30
3.4.3.1 Definition 31
The performance of the demodulation of Forward Traffic Channel during a two-way soft 32
handoff is determined by the frame error rate (FER). 33
3.4.3.2 Method of Measurement 34
1. Connect two base stations and an AWGN generator to the mobile station antenna 35
connector as shown in Figure 6.5.1-2, with both channel simulators set to 36
3GPP2 C.S0011-A Ballot Resolution Version
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configuration 2 (see Table 6.4.1.3-1). The Forward Channel from base station 1 has 1
an arbitrary pilot PN offset index P1, and is called Channel 1. The Forward Channel 2
from base station 2 has an arbitrary pilot PN offset index P2, and is called Channel 3
2. 4
2. For each band class that the mobile station supports, configure the mobile station 5
to operate in that band class and perform steps 3 through 6. 6
3. If the mobile station supports demodulation of Radio Configurations 1, set up a call 7
using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 8
and perform steps 4 through 6. 9
4. Set the test parameters for each test as specified in Table A.2.3.1-1 for both base 10
stations. 11
5. Send a Universal Handoff Direction Message to the mobile station, specifying the 12
following pilots in the Active Set: 13
14
Parameter Value (Decimal)
PILOT_PN P1
PILOT_PN P2
15
6. Count, at the base station, the number of frames transmitted and the number of 16
good frames received at the mobile station. 17
3.4.3.3 Minimum Standard 18
The actual Eb/Nt used in each test shall be within ±0.3 dB of the value indicated in Table 19
A.2.3.1-1. 20
The FER for each test shall not exceed the piece-wise linear FER curve specified by the 21
points in Table A.2.3.2-1 with 95% confidence (see 6.6). 22
3.4.4 Decision of Power Control Bit for Channels Belonging to Different Power Control 23
Sets During Soft Handoff 24
This test shall be performed on the Forward Fundamental Channel with Radio 25
Configuration 1 or 2, if the Forward Fundamental Channel with Radio Configuration 1 or 2 26
is supported by the mobile station. 27
3.4.4.1 Definition 28
When simultaneously receiving channels belonging to different power control sets, the 29
mobile station shall increase its transmit power if all valid power control bits received from 30
all power control sets indicate an increment and shall reduce its transmit power if any valid 31
power control bit received indicates a decrement. This test verifies the above or of downs 32
logic. 33
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3.4.4.2 Method of Measurement 1
1. Connect two base stations to the mobile station antenna connector as shown in 2
Figure 6.5.1-3. The AWGN generator is not applicable in this test. The Forward 3
Channel from base station 1 has an arbitrary pilot PN offset index P1, and is called 4
Channel 1. The Forward Channel from base station 2 has an arbitrary pilot PN 5
offset index P2, and is called Channel 2. 6
2. For each band class that the mobile station supports, configure the mobile station 7
to operate in that band class and perform steps 3 through 10. 8
3. If the mobile station supports demodulation of Radio Configurations 1, set up a call 9
using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 10
and perform steps 5 through 10. 11
4. If the mobile station supports demodulation of Radio Configurations 2, set up a call 12
using Fundamental Channel Test Mode 2 (see 1.3) with 14400 bps data rate only 13
and perform steps 5 through 10. 14
5. Set the test parameters as specified in Table A.2.4.1-1 for both base stations. 15
6. Send a Universal Handoff Direction Message to the mobile station, specifying the 16
following pilots in the Active Set: 17
18
Parameter Value (Decimal)
USE_TIME 0 (no action time)
PILOT_PN P1
PWR_COMB_IND 0
PILOT_PN P2
PWR_COMB_IND 0 (no combining with P1)
19
7. After waiting a minimum of 160 ms, synchronously send a periodic pattern of 20
twenty 0 power control bits followed by twenty 1 power control bits on both 21
Channel 1 and Channel 2. 22
8. Measure the output power at the mobile station antenna connector for a duration 23
of 80 power control groups (100 ms). 24
9. Send a periodic pattern of twenty 0 power control bits followed by twenty 1 power 25
control bits on Channel 1. Send continuously 0 power control bits on Channel 2. 26
10. Measure the output power at the mobile station antenna connector for a duration 27
of 80 power control groups (100 ms). 28
3.4.4.3 Minimum Standard 29
The mobile station output power, measured at the mobile station antenna connector, shall 30
have a periodic pattern. In each period the power shall increase monotonically for a 31
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duration of 20 power control groups (25 ms) and then decrease monotonically for a duration 1
of 20 power control groups. 2
3.4.5 Decision of Power Control Bit for Channels Belonging to the Same Power Control 3
Set 4
This test shall be performed on the Forward Fundamental Channel with Radio 5
Configuration 1 or 2, if the Forward Fundamental Channel with Radio Configuration 1 or 2 6
is supported by the mobile station. 7
3.4.5.1 Definition 8
In each power control group containing valid power control bits, the mobile station should 9
provide diversity combining of identical power control subchannels and shall obtain at most 10
one power control bit from each set of identical power control subchannels. This test 11
partially verifies the diversity combining of power control bits belonging to identical power 12
control subchannels and the diversity combining of power control bits belonging to different 13
paths of the same power control subchannel. 14
3.4.5.2 Method of Measurement 15
1. Connect two base stations to the mobile station antenna connector as shown in 16
Figure 6.5.1-2. The AWGN generators and channel simulators are not applicable in 17
this test. The Forward Channel from base station 1 has an arbitrary pilot PN offset 18
index P1, and is called Channel 1. The Forward Channel from base station 2 has an 19
arbitrary pilot PN offset index P2, and is called Channel 2. 20
2. For each band class that the mobile station supports, configure the mobile station 21
to operate in that band class and perform steps 3 through 8. 22
3. If the mobile station supports demodulation of Radio Configurations 1, set up a call 23
using Fundamental Channel Test Mode 1 (see 1.3) and perform steps 5 through 8. 24
4. If the mobile station supports demodulation of Radio Configurations 2, set up a call 25
using Fundamental Channel Test Mode 2 (see 1.3) and perform steps 5 through 8. 26
5. Set the test parameters as specified in Table A.2.5.1-1 for both base stations. 27
6. Send a Universal Handoff Direction Message to the mobile station, specifying the 28
following pilots in the Active Set: 29
30
Parameter Value (Decimal)
USE_TIME 0 (no action time)
PILOT_PN P1
PWR_COMB_IND 0
PILOT_PN P2
PWR_COMB_IND 1 (combine with P1)
31
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7. After waiting a minimum of 160 ms, begin sending a periodic pattern of one 0 1
power control bit followed by one 1 power control bit on Channel 1 and a sequence 2
of 1 power control bits on Channel 2. 3
8. Measure the output power at the mobile station antenna connector for at least 40 4
power control groups (50 ms) for each trial. Perform at least 11 trials. 5
3.4.5.3 Minimum Standard 6
In 90% of the trials (each with at least 40 power control groups), the mobile station output 7
power, measured at the mobile station antenna connector, shall follow the power control bit 8
pattern of alternating 0 and 1 sent on Channel 1, with the exception of at most one bit per 9
trial. 10
3.4.6 Demodulation of Power Control Subchannel During Soft Handoff 11
This test shall be performed on the Forward Fundamental Channel with Radio 12
Configuration 1 or 2, if the Forward Fundamental Channel with Radio Configuration 1 or 2 13
is supported by the mobile station. 14
3.4.6.1 Definition 15
The mobile station shall not use a power control subchannel when the pilot Ec/I0 of the 16
corresponding CDMA Channel is low. This test verifies that the mobile station stops using a 17
power control subchannel in the or of downs when the pilot Ec/I0 of the corresponding 18
CDMA Channel is low. 19
3.4.6.2 Method of Measurement 20
1. Connect two base stations to the mobile station antenna connector as shown in 21
Figure 6.5.1-3. The AWGN generator is not applicable in this test. The Forward 22
Channel from base station 1 has an arbitrary pilot PN offset index P1, and is called 23
Channel 1. The Forward Channel from base station 2 has an arbitrary pilot PN 24
offset index P2, and is called Channel 2. 25
2. For each band class that the mobile station supports, configure the mobile station 26
to operate in that band class and perform steps 3 through 8. 27
3. If the mobile station supports demodulation of Radio Configurations 1, set up a call 28
using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 29
and perform steps 5 through 8. 30
4. If the mobile station supports demodulation of Radio Configurations 2, set up a call 31
using Fundamental Channel Test Mode 2 (see 1.3) ) with 14400 bps data rate only 32
and perform steps 5 through 8. 33
5. Set the test parameters as specified in Table A.2.6.1-1 and Figure 3.4.6.2-1 for both 34
base stations. 35
6. Send a Universal Handoff Direction Message to the mobile station, specifying the 36
following pilots in the Active Set: 37
38
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Parameter Value (Decimal)
USE_TIME 0 (no action time)
PILOT_PN P1
PWR_COMB_IND 0
PILOT_PN P2
PWR_COMB_IND 0 (no combining with P1)
1
7. After waiting a minimum of 160 ms, synchronously send a periodic pattern of one 2
0 power control bit followed by one 1 power control bit on both Channel 1 and 3
Channel 2. 4
8. Measure the mobile station output power at the mobile station antenna connector 5
for at least 22 seconds, which does not have to be contiguous. The 22-second 6
period must contain at least 11 transitions from the state where Channel 2 Pilot 7
Ec/I0 changes from -10 dB to -20 dB. 8
9
10 dB
Channel 1 Pilot
Channel 2 Pilot
Pilot Ec/Io = -10 dB
1 1 1 1 Time (s) 10
Figure 3.4.6.2-1. Demodulation of Power Control Subchannel During Soft Handoff 11
3.4.6.3 Minimum Standard 12
The mobile station output power, measured at the mobile station antenna connector, shall 13
be in a steady state, defined as steady state 1, when the pilot Ec/I0 value of Channel 2 is 14
-10 dB, and it shall follow the power control bit pattern of alternating 0 and 1 in 85% of 15
the 1-second steady state 1 segments with 90% confidence. The mobile station output 16
power shall be in a steady state, defined as steady state 2, no later than 40 ms after the 17
pilot Ec/I0 value of Channel 2 drops to -20 dB in 90% of the trials, and shall follow the 18
power control bit pattern of alternating 0 and 1. The mobile station output power in 19
steady state 2 shall be no greater than the mobile station output power in steady state 1, 20
and shall be greater than the mobile station output power in steady state 1 minus 12 dB. 21
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3.4.7 Demodulation of Forward Traffic Channel in Multipath Fading Channel with Closed 1
Loop Power Control (FPC_MODE = 000) 2
This test shall be performed for each band class supported by the mobile station. This test 3
shall be performed on the Forward Fundamental Channel, if the Forward Fundamental 4
Channel is supported by the mobile station. Otherwise, this test shall be performed on the 5
Forward Dedicated Control Channel. Forward Traffic Channel closed loop power control in 6
the base station shall be enabled during this test. 7
3.4.7.1 Definition 8
When operating with radio configurations greater than or equal to 3, the mobile station 9
supports both inner power control loop and outer power control loop for Forward Traffic 10
Channel power control. To maintain the Frame Error Rate (FER) of the Forward Traffic 11
Channel, the mobile station inner power control loop measures the Eb/Nt of the received 12
Forward Traffic Channel, and compares it with the corresponding outer power control loop 13
setpoint. The power control bits are transmitted to the base station on the Reverse Power 14
Control Subchannel. When FPC_MODE equals 000, the mobile station uses the 800 bps 15
Primary Reverse Power Control Subchannel to support Forward Traffic Channel power 16
control. 17
The performance of forward power control is measured by the differences between the 18
mobile station received FER and the assigned target FER while not exceeding the specified 19
Traffic Eb/Nt limits. The FER is calculated for each individual data rate. The FER is 20
calculated for active frames only. 21
3.4.7.2 Method of Measurement 22
1. Connect the base station and an AWGN generator to the mobile station antenna 23
connector as shown in Figure 6.5.1-1. 24
2. For each band class that the mobile station supports, configure the mobile station 25
to operate in that band class and perform steps 3 through 11. 26
3. If the mobile station supports demodulation of Radio Configuration 3 or 4, set up a 27
call using Fundamental Channel Test Mode 3 or Dedicated Control Channel Test 28
Mode 3 with 100% frame activity (see 1.3) and perform steps 7 through 11. 29
4. If the mobile station supports demodulation of Radio Configuration 5, set up a call 30
using Fundamental Channel Test Mode 5 or Dedicated Control Channel Test Mode 31
5 with 100% frame activity (see 1.3) and perform steps 7 through 11. 32
5. If the mobile station supports demodulation of Radio Configuration 6, 7, or 8, set 33
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 34
Test Mode 7 with 100% frame activity (see 1.3) and perform steps 7 through 11. 35
6. If the mobile station supports demodulation of Radio Configuration 9, set up a call 36
using Fundamental Channel Test Mode 9 or Dedicated Control Channel Test Mode 37
9 with 100% frame activity (see 1.3) and perform steps 7 through 11. 38
7. Set the parameters of each test as specified in Tables A.2.7.1-1 through A.2.7.1-9. 39
Tests that are not supported by the mobile station may be omitted. 40
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8. When performing the test on the Fundamental Channel, transmit random data to 1
the mobile station on the Forward Fundamental Channel at a fixed data rate. When 2
performing the test on the Dedicated Control Channel, transmit random data to the 3
mobile station on the Forward Dedicated Control Channel at one fixed data rate. 4
9. Activate the Forward Traffic Channel power control and command the base station 5
to respond to the power control bits received on the Reverse Power Control 6
Subchannel. Set the base station to limit its output traffic channel power to the 7
maximum Traffic Ec/Ior value specified in Table A.2.7.1-1. 8
10. Adjust the mobile station transmission power so that no bit errors on the Reverse 9
Power Control Subchannel are expected at the base station receiver. 10
11. Count at the base station the number of Forward Traffic Channel frames 11
transmitted and the number of good Forward Traffic Channel frames received at the 12
mobile station. 13
3.4.7.3 Minimum Standard 14
The actual FCH Eb/Nt or DCCH Eb/Nt used in each test shall be within ±0.5 dB of the 15
value indicated in Tables A.2.7.1-2 through A.2.7.1-9. 16
For Tests 1, 2, 7, 8, 13, 14, 19, 20, 25, 26, 31, 32, 37, 38, 43, 44, and 49-60, the mobile 17
station received FER on the Forward Fundamental Channel or the Forward Dedicated 18
Control Channel shall not exceed 10% ±0.5% with 95% confidence (see 6.6). 19
For Tests 3-6, 9-12, 15-18, 21-24, 27-30, 33-36, 39-42, and 45-48, the mobile station 20
received FER on the Forward Fundamental Channel or the Forward Dedicated Control 21
Channel shall not exceed 1% ±0.5% with 95% confidence (see 6.6). 22
The required FCH Eb/Nt or DCCH Eb/Nt to achieve the specified FER shall not exceed the 23
piece-wise linear values shown in Tables A.2.7.2-1 through A 2.7.2-8. 24
3.4.8 Demodulation of Forward Traffic Channel in Multipath Fading Channel with Closed 25
Loop Power Control (FPC_MODE = 010) 26
This test shall be performed for each band class supported by the mobile station. This test 27
shall be performed on the Forward Supplemental Channel, if the Forward Supplemental 28
Channel is supported by the mobile station. Forward Traffic Channel closed loop power 29
control in the base station shall be enabled during this test. 30
3.4.8.1 Definition 31
When operating with radio configurations greater than or equal to 3, the mobile station 32
supports both inner power control loop and outer power control loop for Forward Traffic 33
Channel power control. To maintain the Frame Error Rate (FER) of the Forward 34
Supplemental Channel, the mobile station inner power control loop measures the Eb/Nt of 35
the received Forward Supplemental Channel, and compares it with the corresponding outer 36
power control loop setpoint. The power control bits are transmitted to the base station on 37
the Reverse Power Control Subchannel. When FPC_MODE equals 010, the mobile station 38
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uses the 600 bps Secondary Reverse Power Control Subchannel to support Forward 1
Supplemental Channel power control. 2
The performance of forward power control is measured by the differences between the 3
mobile station received FER and the assigned target FER while not exceeding the specified 4
Supplemental Eb/Nt limits. The FER is calculated for the lowest fixed data rate and highest 5
fixed data rate supported by the mobile station. The FER is calculated for active frames 6
only. 7
3.4.8.2 Method of Measurement 8
1. Connect the base station and an AWGN generator to the mobile station antenna 9
connector as shown in Figure 6.5.1-1. 10
2. For each band class that the mobile station supports, configure the mobile station 11
to operate in that band class and perform steps 3 through 12. 12
3. If the mobile station supports demodulation of Radio Configuration 3 or 4, set up a 13
call using Supplemental Channel Test Mode 3 with 100% frame activity (see 1.3) 14
and perform steps 7 through 12. 15
4. If the mobile station supports demodulation of Radio Configuration 5, set up a call 16
using Supplemental Channel Test Mode 5 with 100% frame activity (see 1.3) and 17
perform steps 7 through 12. 18
5. If the mobile station supports demodulation of Radio Configuration 6, 7, or 8, set 19
up a call using Supplemental Channel Test Mode 7 with 100% frame activity (see 20
1.3) and perform steps 7 through 12. 21
6. If the mobile station supports demodulation of Radio Configuration 9, set up a call 22
using Supplemental Channel Test Mode 9 with 100% frame activity (see 1.3) and 23
perform steps 7 through 12. 24
7. Transmit random data to the mobile station on the Forward Supplemental Channel 25
at the lowest fixed data rate, as specified in Tables A.2.8.1-2 through A.2.8.1-5, 26
supported by the mobile station. 27
8. Set the parameters of each test as specified in Tables A.2.8.1-1 through A.2.8.1-5. 28
Tests that are not supported by the mobile station may be omitted. 29
9. Activate the Forward Traffic Channel power control and command the base station 30
to respond to the power control bits received on the Reverse Power Control 31
Subchannel. Set the base station to limit its output traffic channel power to the 32
maximum Supplemental Ec/Ior value shown in Table A.2.8.1-1. 33
10. Adjust the mobile station transmission power so that no bit errors on the Reverse 34
Power Control Subchannel are expected at the base station receiver. 35
11. Count at the base station the number of Forward Supplemental Channel frames 36
transmitted and the number of good Forward Supplemental Channel frames 37
received at the mobile station. 38
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12. Transmit random data to the mobile station on the Forward Supplemental Channel 1
at the highest fixed data rate supported by the mobile station and repeat steps 8 2
through 11. 3
3.4.8.3 Minimum Standard 4
The actual Supplemental Eb/Nt used in each test shall be within ±0.5 dB of the value 5
indicated in Tables A.2.8.1-2 through A.2.8.1-5. 6
For Tests 1-6, 11-16, 21, 22, 24, 25, 31, 32, 34, 35, 41-52, 57-68, 73-84, and 89-100, the 7
mobile station received FER on the Forward Supplemental Channel shall not exceed 5% 8
±0.5% with 95% confidence (see 6.6). 9
For Tests 7-10, 17-20, 23, 26-30, 33, 36-40, 53-56, 69-72, 85-88, and 101-104, the mobile 10
station received FER on the Forward Supplemental Channel shall not exceed 10% ±0.5% 11
with 95% confidence (see 6.6). 12
The required SCH Eb/Nt to achieve the specified FER shall not exceed the piece-wise linear 13
values shown in Tables A.2.8.2-1 through A 2.8.2-4. 14
3.4.9 Demodulation of Forward Traffic Channel in Multipath Fading Channel with Outer 15
Loop Power Control and Closed Loop Power Control (FPC_MODE = 000, 001 and 16
010) 17
This test shall be performed for each band class supported by the mobile station. This test 18
shall be performed on the Forward Fundamental Channel, if the Forward Fundamental 19
Channel is supported by the mobile station. Otherwise, this test shall be performed on the 20
Forward Dedicated Control Channel. Forward Traffic Channel open loop and closed loop 21
power control in the base station shall be enabled during this test. 22
3.4.9.1 Definition 23
This test measures the performance of slow power control by checking the average Traffic 24
Eb/Nt at the base station under a given frame error constraint and channel simulator 25
configuration. 26
3.4.9.2 Method of Measurement 27
1. Connect the base station and an AWGN generator to the mobile station antenna 28
connector as shown in Figure 6.5.1-1. 29
2. For each band class that the mobile station supports, configure the mobile station 30
to operate in that band class and perform steps 3 through 7. 31
3. If the mobile station supports demodulation of Radio Configuration 3 or 4, set up a 32
call using Fundamental Channel Test Mode 3 or Dedicated Control Channel Test 33
Mode 3 with 100% frame activity (see 1.3) and perform steps 7 through 11. 34
4. If the mobile station supports demodulation of Radio Configuration 5, set up a call 35
using Fundamental Channel Test Mode 5 or Dedicated Control Channel Test Mode 36
5 with 100% frame activity (see 1.3) and perform steps 7 through 11. 37
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5. If the mobile station supports demodulation of Radio Configuration 6, 7, or 8, set 1
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 2
Test Mode 7 with 100% frame activity (see 1.3) and perform steps 7 through 11. 3
6. If the mobile station supports demodulation of Radio Configuration 9, set up a call 4
using Fundamental Channel Test Mode 9 or Dedicated Control Channel Test Mode 5
9 with 100% frame activity (see 1.3) and perform steps 7 through 11. 6
7. Set the parameters of each test as specified in Tables A.2.9.1-1 through A.2.9.1-5. 7
Tests that are not supported by the mobile station may be omitted. 8
8. When performing the test on the Fundamental Channel, transmit random data to 9
the mobile station on the Forward Fundamental Channel at a fixed data rate. When 10
performing the test on the Dedicated Control Channel, transmit random data to the 11
mobile station on the Forward Dedicated Control Channel at one fixed data rate. 12
9. Activate the Forward Traffic Channel power control and command the base station 13
to respond to both the power control bits received on the Reverse Power Control 14
Subchannel and the outer loop report messages sent by the mobile station. Set the 15
base station to limit its output traffic channel power to the maximum Traffic Ec/Ior 16
value specified in Table A.2.9.1-1. 17
10. Adjust the mobile station transmission power so that no bit errors on the Reverse 18
Power Control Subchannel are expected at the base station receiver. 19
11. Count at the base station the number of Forward Traffic Channel frames 20
transmitted and the number of good Forward Traffic Channel frames received at the 21
mobile station. 22
3.4.9.3 Minimum Standard 23
The required Traffic Eb/Nt to achieve the specified FER shall not exceed the values specified 24
in Tables A.2.9.2-1 through A 2.9.2-4. 25
3.4.10 Demodulation of Forward Traffic Channel in Multipath Fading Channel with Closed 26
Loop Power Control (FPC_MODE = 000) and Transmit Diversity (OTD or STS) 27
This test shall be performed for each transmit diversity scheme (i.e. OTD or STS) supported 28
by the mobile station. Forward Traffic Channel closed loop power control in the base station 29
shall be enabled during this test. 30
3.4.10.1 Definition 31
The performance of the demodulation of Forward Traffic Channel with closed loop power 32
control and transmit diversity is tested. 33
3.4.10.2 Method of Measurement 34
1. Connect the base station and an AWGN generator to the mobile station antenna 35
connector as shown in Figure 6.5.1-1. 36
2. For each band class that the mobile station supports, configure the mobile station 37
to operate in that band class and perform steps 3 through 13. 38
3GPP2 C.S0011-A Ballot Resolution Version
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3. If the mobile station supports demodulation of Radio Configuration 3 or 4, set up a 1
call using Fundamental Channel Test Mode 3 or Dedicated Control Channel Test 2
Mode 3 with 100% frame activity (see 1.3) and perform steps 7 through 13. 3
4. If the mobile station supports demodulation of Radio Configuration 3 or 4, and the 4
Forward Dedicated Control Channel, set up a call using Dedicated Control Channel 5
Test Mode 3 with 10% frame activity (see 1.3) and perform steps 7 through 13. 6
5. If the mobile station supports demodulation of Radio Configuration 5, set up a call 7
using Fundamental Channel Test Mode 5 or Dedicated Control Channel Test Mode 8
5 with 100% frame activity (see 1.3) and perform steps 7 through 13. 9
6. If the mobile station supports demodulation of Radio Configuration 5 and the 10
Forward Dedicated Control Channel, set up a call using Dedicated Control Channel 11
Test Mode 5 with 10% frame activity (see 1.3) and perform steps 7 through 13. 12
7. Set the following parameters in the Sync Channel Message: 13
14
Parameter Value (Binary)
SR1_TD_INCL 1 (Transmit Diversity enabled)
SR1_TD_POWER_LEVEL 10 (3 dB below the Forward Pilot Channel transmit power)
15
8. Set the test parameters for each test as specified in Tables A.2.10.1-2 through 16
A.2.10.1-9. Tests that are not supported by the mobile station may be omitted. 17
9. When performing the test on the Fundamental Channel, transmit random data to 18
the mobile station on the Forward Fundamental Channel at a fixed data rate. When 19
performing the test on the Dedicated Control Channel, transmit random data to the 20
mobile station on the Forward Dedicated Control Channel at one fixed data rate. 21
Control the enabling and disabling of frame transmission according to the frame 22
activity. 23
10. Activate the Forward Traffic Channel power control and command the base station 24
to respond to the power control bits received on the Reverse Power Control 25
Subchannel. Set the base station to limit its output traffic channel power to the 26
maximum Traffic Ec/Ior values shown in Table A.2.10.1-1. 27
11. Adjust the mobile station transmission power so that no bit errors on the Reverse 28
Power Control Subchannel are expected at the base station receiver. 29
12. Count at the base station the number of Forward Traffic Channel frames 30
transmitted and the number of good Forward Traffic Channel frames received at the 31
mobile station. 32
13. Repeat the test for each transmit diversity scheme (e.g. OTD or STS) supported by 33
the mobile station. 34
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3.4.10.3 Minimum Standard 1
The actual FCH Eb/Nt or DCCH Eb/Nt used in each test shall be within ±0.5 dB of the 2
value indicated in Tables A.2.10.1-2 through A.2.10.1-9. 3
For Tests 1, 2, 5, 6, 9, 10, 13, 14, 17, 18, 21, 22, 25, 26, 29, 30, 33-44, the mobile station 4
received FER on the Forward Fundamental Channel or the Forward Dedicated Control 5
Channel shall not exceed 10% ±0.5% with 95% confidence (see 6.6). 6
For Tests 3, 4, 7, 8, 11, 12, 15, 16, 19, 20, 23, 24, 27, 28, 31, and 32, the mobile station 7
received FER on the Forward Fundamental Channel or the Forward Dedicated Control 8
Channel shall not exceed 1% ±0.5% with 95% confidence (see 6.6). 9
The required FCH Eb/Nt or DCCH Eb/Nt to achieve the specified FER shall not exceed the 10
piece-wise linear values shown in Tables A.2.10.2-1 through A 2.10.2-8. 11
3.4.11 Demodulation of Forward Traffic Channel in Multipath Fading Channel with Closed 12
Loop Power Control (FPC_MODE = 010) and Transmit Diversity (OTD or STS) 13
This test shall be performed for each transmit diversity scheme (i.e. OTD or STS) supported 14
by the mobile station. Forward Traffic Channel closed loop power control in the base station 15
shall be enabled during this test. 16
3.4.11.1 Definition 17
The performance of the demodulation of Forward Supplemental Channel with closed loop 18
power control and transmit diversity is tested. 19
3.4.11.2 Method of Measurement 20
1. Connect the base station and an AWGN generator to the mobile station antenna 21
connector as shown in Figure 6.5.1-1. 22
2. For each band class that the mobile station supports, configure the mobile station 23
to operate in that band class and perform steps 3 through 11. 24
3. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 25
up a call using Supplemental Channel Test Mode 3 with 100% frame activity (see 26
1.3) and perform steps 5 through 11. 27
4. If the mobile station supports demodulation of Radio Configuration 5, set up a call 28
using Supplemental Channel Test Mode 5 with 100% frame activity (see 1.3) and 29
perform steps 5 through 11. 30
5. Set the following parameters in the Sync Channel Message: 31
32
Parameter Value (Binary)
SR1_TD_INCL 1 (Transmit Diversity enabled)
SR1_TD_POWER_LEVEL 10 (3 dB below the Forward Pilot Channel transmit power)
33
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6. Set the test parameters for each test as specified in Tables A.2.11.1-2 through 1
A.2.11.1-5. Tests that are not supported by the mobile station may be omitted. 2
7. Transmit random data to the mobile station on the Forward Supplemental Channel 3
at one fixed data rate. 4
8. Activate the Forward Traffic Channel power control and command the base station 5
to respond to the power control bits received on the Reverse Power Control 6
Subchannel. Set the base station to limit its output traffic channel power to the 7
maximum Supplemental Ec/Ior value shown in Table A.2.11.1-1. 8
9. Adjust the mobile station transmission power so that no bit errors on the Reverse 9
Power Control Subchannel are expected at the base station receiver. 10
10. Count at the base station the number of Forward Supplemental Channel frames 11
transmitted and the number of good Forward Supplemental Channel frames 12
received at the mobile station. 13
11. Repeat the test for each transmit diversity scheme (e.g. OTD or STS) supported by 14
the mobile station. 15
3.4.11.3 Minimum Standard 16
The actual SCH Eb/Nt used in each test shall be within ±0.5 dB of the value indicated in 17
Tables A.2.11.1-2 through A.2.11.1-5. 18
The mobile station received FER on the Forward Supplemental Channel shall not exceed 19
10% ±0.5% with 95% confidence (see 6.6). 20
The required SCH Eb/Nt to achieve the specified FER shall not exceed the piece-wise linear 21
values shown in Tables A.2.11.2-1 through A 2.11.2-4. 22
3.4.12 Demodulation of Power Control Subchannel During Reverse Pilot Channel Gating 23
This test shall be performed on the Forward Dedicated Control Channel, if supported by the 24
mobile station. 25
3.4.12.1 Definition 26
The mobile station shall not use a power control bit that corresponds to a gated off period 27
on the reverse link during Reverse Pilot Channel Gating. This test verifies that the mobile 28
station does not use these invalid power control bits. 29
3.4.12.2 Method of Measurement 30
1. Connect the base station to the mobile station antenna connector as shown in 31
Figure 6.5.1-4. 32
2. For each band class that the mobile station supports, configure the mobile station 33
to operate in that band class and perform steps 3 through 7. 34
3. If the mobile station supports Reverse Radio Configuration 3 or 4, and if the mobile 35
station supports Reverse Pilot Channel gating, set up a call using Dedicated Control 36
Channel Test Mode 3 (see 1.3). Send Non-Negotiable Service Configuration 37
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information record messages to the mobile station, so that 1
PILOT_GATING_USE_RATE = 1 and PILOT_GATING_RATE = 10 (1/4 rate). The 2
base station shall not transmit on the Forward Dedicated Control Channel to the 3
mobile station under test during the test. Perform steps 5 through 7. 4
4. If the mobile station supports Reverse Radio Configuration 5 or 6, and if the mobile 5
station supports Reverse Pilot Channel gating, set up a call using Dedicated Control 6
Channel Test Mode 7 (see 1.3). Send Non-Negotiable Service Configuration 7
information record messages to the mobile station, so that 8
PILOT_GATING_USE_RATE = 1 and PILOT_GATING_RATE = 10 (1/4 rate). The 9
base station shall not transmit on the Forward Dedicated Control Channel to the 10
mobile station under test during the test. Perform steps 5 through 7. 11
5. Set the test parameters as specified in Table A.2.12.1-1. Set the reverse power 12
control delay test parameter, REV_PWR_CNTL_DELAY, to what the base station is 13
using. 14
6. After waiting a minimum of 160 ms, send a periodic pattern of four 0 power 15
control bits followed by four 1 power control bits on the Forward Power Control 16
Subchannel regardless of whether these bits would be considered by the mobile 17
station as valid or not. 18
7. Measure the mobile station output power at the mobile station antenna connector 19
for at least 5 seconds. 20
3.4.12.3 Minimum Standard 21
The mobile station output power, measured at the mobile station antenna connector, shall 22
follow the valid power control bit pattern in 85% of the trials. 23
3.4.13 Demodulation of Power Control Subchannel During Reverse Fundamental Channel 24
Gating 25
3.4.13.1 Definition 26
The mobile station shall not use a power control bit that corresponds to a gated off period 27
on the reverse link during Reverse Fundamental Channel Gating. This test verifies that the 28
mobile station does not use these invalid power control bits. 29
3.4.13.2 Method of Measurement 30
1. Connect the base station to the mobile station antenna connector as shown in 31
Figure 6.5.1-4. 32
2. For each band class that the mobile station supports, configure the mobile station 33
to operate in that band class and perform steps 3 through 7. 34
3. If the mobile station supports Reverse Radio Configuration 3 or 4, set up a call 35
using Fundamental Channel Test Mode 3 (see 1.3). Send an Extended Channel 36
Assignment Message to the mobile station with REV_FCH_GATING_MODE equal to 37
1 (50% R-FCH transmission duty cycle). The base station shall transmit 38
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continuous 20 ms frames at 1500 bps on the Forward Fundamental Channel to the 1
mobile station under test during the test. Perform steps 5 through 7. 2
4. If the mobile station supports Reverse Radio Configuration 5 or 6, set up a call 3
using Fundamental Channel Test Mode 7 (see 1.3). Send an Extended Channel 4
Assignment Message to the mobile station with REV_FCH_GATING_MODE equal to 5
1 (50% R-FCH transmission duty cycle). The base station shall transmit 6
continuous 20 ms frames at 1500 bps on the Forward Fundamental Channel to the 7
mobile station under test during the test. Perform steps 5 through 7. 8
5. Set the test parameters as specified in A.2.13.1-1. Set the reverse power control 9
delay test parameter, REV_PWR_CNTL_DELAY, to what the base station is using. 10
6. After waiting a minimum of 160 ms, send a periodic pattern of one 0 power control 11
bit followed by one 1 power control bit on the Forward Power Control Subchannel, 12
regardless of whether these bits would be considered by the mobile station as valid 13
or not. 14
7. Measure the mobile station output power at the mobile station antenna connector 15
for at least 5 seconds 16
3.4.13.3 Minimum Standard 17
The mobile station output power, measured at the mobile station antenna connector, shall 18
follow the valid power control bit pattern in 85% of the trials. 19
3.5 Receiver Performance 20
3.5.1 Receiver Sensitivity and Dynamic Range 21
3.5.1.1 Definition 22
The RF sensitivity of the mobile station receiver is the minimum received power, measured 23
at the mobile station antenna connector, at which the frame error rate (FER) does not 24
exceed a specified value. The receiver dynamic range is the input power range at the mobile 25
station antenna connector over which the FER does not exceed a specific value. 26
3.5.1.2 Method of Measurement 27
1. Connect the base station to the mobile station antenna connector as shown in 28
Figure 6.5.1-4. The AWGN generator and the interference generator are not 29
applicable in this test. 30
2. For all tests, Forward Traffic Channel closed loop power control should be disabled 31
in the base station. 32
3. For each band class that the mobile station supports, configure the base station to 33
operate in that band class and perform steps 4 through 8. 34
4. If the mobile station supports demodulation of Radio Configuration 1, 2, 3, 4, or 5, 35
set up a call using Fundamental Channel Test Mode 1 or 3 or Dedicated Control 36
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Channel Test Mode 3 (see 1.3) with 9600 or 14400 bps data rate only and perform 1
steps 6 through 8. 2
5. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 3
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 4
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 6 through 8. 5
6. Set the test parameters for Test 1 as specified in Table 3.5.1.2-1 and perform step 6
8. 7
7. Set the test parameters for Test 2 as specified in Table 3.5.1.2-1 and perform step 8
8. 9
8. Count, at the base station, the number of frames transmitted and the number of 10
good frames received at the mobile station. 11
12
Table 3.5.1.2-1. Test Parameters for Receiver Sensitivity and Dynamic Range 13
Parameter Units Test 1 Test 2
Îor dBm/1.23 MHz -104 -25
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (RC 1 and 3) -12.3 (RC 2) -20.6 (RC 7)
For the case of a Spreading Rate 3 system, Îor is the received power on eachcarrier.
3.5.1.3 Minimum Standard 14
The FER in each test shall not exceed 0.5% with 95% confidence (see 6.6). 15
3.5.2 Single Tone Desensitization 16
3.5.2.1 Definition 17
Single tone desensitization is a measure of a receivers ability to receive a CDMA signal at 18
its assigned channel frequency in the presence of a single tone spaced at a given frequency 19
offset from the center frequency of the assigned channel. The receiver desensitization 20
performance is measured by the frame error rate (FER). 21
This test is applied to all band classes except Band Class 6, where no narrow-band 22
interferers are currently known. However, Japanese Radio Law currently requires that this 23
test be performed for mobile stations operating in Japan that support Band Class 6 using 24
the test methods described below for Band Class 1. 25
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3.5.2.2 Method of Measurement 1
1. Connect the base station and an interfering CW tone to the mobile station antenna 2
connector as shown in Figure 6.5.1-4. 3
2. For all tests, Forward Traffic Channel closed loop power control should be disabled 4
in the base station. 5
3. For each band class that the mobile station supports, except Band Class 6, 6
configure the base station to operate in that band class and perform steps 4 7
through 12. 8
4. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 9
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 10
and perform steps 7 through 12. 11
5. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 12
up a call using Fundamental Channel Test Mode 1 or 3 or Dedicated Control 13
Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 7 14
through 12. 15
6. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 16
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 17
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 7 through 12. 18
7. Set the test parameters for Test 1 as specified in Table 3.5.2.2-1 and perform steps 19
11 and 12. 20
8. Set the test parameters for Test 2 as specified in Table 3.5.2.2-1 and perform steps 21
11 and 12. 22
9. If the mobile station is operating in Band Class 1, 3, 4, or 8 with Radio 23
Configuration 3 or 7, set the test parameters for Test 3 and perform steps 11 and 24
12. 25
10. If the mobile station is operating in Band Class 1, 3, 4, or 8 with Radio 26
Configuration 3 or 7, set the test parameters for Test 4 and perform steps 11 and 27
12. 28
11. If the mobile station is operating in Band Class 1, 3, 4, or 8, use closed loop power 29
control commands to adjust the mobile station transmit power, as measured at the 30
mobile station antenna connector. For Band Class 1, 4, and 8, using the antenna 31
gain recommended by the mobile station manufacturer, set the EIRP to a level 32
higher than the minimum specified in Table 3.5.2.2-2 for the current test. For Band 33
Class 3, set the ERP to a level higher than the minimum specified in Table 3.5.2.2-34
3 for the current test. 35
12. Count, at the base station, the number of frames transmitted and the number of 36
good frames received at the mobile station. 37
38
3GPP2 C.S0011-A Ballot Resolution Version
3-87
Table 3.5.2.2-1. Test Parameters for Single Tone Desensitization 1
Parameter Units Tests 1 and 3 Tests 2 and 4
Tone Offset from Carrier
SR 1 kHz +900 (BC 0, 2, 3, 5, 7 and 9)
+1250 (BC 1, 4, and 8)
-900 (BC 0, 2, 3, 5, 7 and 9)
1250 (BC 1, 4, and 8)
SR 3 kHz +25004 -2500
Tone Power dBm -30 (Tests 1 and 2) -40 (Tests 3 and 4)
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
2
Table 3.5.2.2-2. Minimum Effective Isotropic Radiated Power for Single Tone 3
Desensitization Test for Band Classes 1, 4, and 8 4
Minimum Mobile Station EIRP Mobile Station Class Tests 1 and 2 Tests 3 and 4
I -10 dBW (100 mW) -5 dBW (320 mW)
II -15 dBW (32 mW) -10 dBW (100 mW)
III -18 dBW (16 mW) -15 dBW (32 mW)
IV -21 dBW (8 mW) -20 dBW (10 mW)
V -24 dBW (4 mW) -25 dBW (3.2 mW)
5
4 When a Spreading Rate 3 system is overlaid on either of the Primary CDMA Channels for Band Class 0, the position of the closest interferer (AMPS paging channel) is 2.13 MHz away from the center of the Spreading Rate 3 signal. To minimize the potential for interference, a base station operating in a Spreading Rate 3 mode should not overlay the Primary CDMA Channel when operating in Band Class 0 unless the CDMA base station is co-located with the AMPS base station.
3GPP2 C.S0011-A Ballot Resolution Version
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Table 3.5.2.2-3. Minimum Effective Radiated Power for Single Tone Desensitization 1
Test for Band Class 3 2
Minimum Mobile Station ERP Mobile Station Class Tests 1 and 2 Tests 3 and 4
I -7 dBW (200 mW) -2 dBW (630 mW)
II -11 dBW (80 mW) -6 dBW (250 mW)
III -15 dBW (32 mW) -10 dBW (100 mW)
3
3.5.2.3 Minimum Standard 4
The FER in each test shall not exceed 1.0% with 95% confidence (see 6.6). 5
The intermodulation spurious response attenuation is a measure of a receiver's ability to 8
receive a CDMA signal on its assigned channel frequency in the presence of two interfering 9
CW tones. These tones are separated from the assigned channel frequency and are 10
separated from each other such that the third order mixing of the two interfering CW tones 11
can occur in the non-linear elements of the receiver, producing an interfering signal in the 12
band of the desired CDMA signal. The receiver performance is measured by the frame error 13
rate (FER). 14
3.5.3.2 Method of Measurement 15
1. Connect the base station and two interfering CW tones to the mobile station 16
antenna connector as shown in Figure 6.5.1-4. 17
2. For all tests, Forward Traffic Channel closed loop power control should be disabled 18
in the base station. 19
3. For each band class that the mobile station supports, configure the base station to 20
operate in that band class and perform steps 4 through 13. 21
4. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 22
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 23
and perform steps 7 through 13. 24
5. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 25
up a call using Fundamental Channel Test Mode 1 or 3 or Dedicated Control 26
Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 7 27
through 13. 28
6. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 29
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 30
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 7 through 13. 31
3GPP2 C.S0011-A Ballot Resolution Version
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7. Set the test parameters for Test 1 as specified in Table 3.5.3.2-1, 3.5.3.2-2, or 1
3.5.3.2-3 and perform step 13. 2
8. Set the test parameters for Test 2 as specified in Table 3.5.3.2-1, 3.5.3.2-2, or 3
3.5.3.2-3 and perform step 13. 4
9. If the mobile station is operating in Band Class 0, set the test parameters for Test 3 5
as specified in Table 3.5.3.2-4 and perform step 13. 6
10. If the mobile station is operating in Band Class 0, set the test parameters for Test 4 7
as specified in Table 3.5.3.2-4 and perform step 13. 8
11. If the mobile station is operating in Band Class 0, set the test parameters for Test 5 9
as specified in Table 3.5.3.2-5 and perform step 13. 10
12. If the mobile station is operating in Band Class 0, set the test parameters for Test 6 11
as specified in Table 3.5.3.2-5 and perform step 13. 12
13. Count, at the base station, the number of frames transmitted and the number of 13
good frames received at the mobile station. 14
15
Table 3.5.3.2-1. Test Parameters for Band Classes 0, 2, 3, 5, 7 and 9 Intermodulation 16
Spurious Response Attenuation (Tests 1 and 2) 17
Mobile Station Class I
Mobile Station Class II and III
Parameter Units Test 1 Test 2 Test 1 Test 2
SR 1 kHz +900 -900 +900 -900 Tone 1 Offset from Carrier SR 3 MHz +2.50 -2.50 +2.50 -2.50
Tone Power 1 dBm -40 -43
SR 1 kHz +1700 -1700 +1700 -1700 Tone 2 Offset from Carrier SR 3 MHz +3.30 -3.30 +3.30 -3.30
Tone Power 2 dBm -40 -43
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
When operating a Spreading Rate 3 system that is overlaid on a Spreading Rate 1carrier, the Spreading Rate 1 intermodulation tests shall not apply.
18
3GPP2 C.S0011-A Ballot Resolution Version
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Table 3.5.3.2-2. Test Parameters for Band Class 1, 4, and 8 Intermodulation Spurious 1
Response Attenuation (Tests 1 and 2) 2
Mobile Station Class I
Mobile Station Class II through Class
V
Parameter Units Test 1 Test 2 Test 1 Test 2
SR 1 MHz +1.25 -1.25 +1.25 -1.25 Tone 1 Offset from Carrier SR 3 MHz +2.50 -2.50 +2.50 -2.50
Tone Power 1 dBm -40 -43
SR 1 MHz +2.05 -2.05 +2.05 -2.05 Tone 2 Offset from Carrier SR 3 MHz +3.30 -3.30 +3.30 -3.30
Tone Power 2 dBm -40 -43
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
When operating a Spreading Rate 3 system that is overlaid on a Spreading Rate 1 carrier, the Spreading Rate 1 intermodulation tests shall not apply.
3
3GPP2 C.S0011-A Ballot Resolution Version
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Table 3.5.3.2-3. Test Parameters for Band Class 6 Intermodulation Spurious Response 1
Attenuation (Tests 1 and 2) 2
Mobile Station Class I
Mobile Station Class II through Class
V
Parameter Units Test 1 Test 2 Test 1 Test 2
SR 1 MHz +2.5 -2.5 +2.5 -2.5 Tone 1 Offset from Carrier SR 3 MHz +5 -5 +5 -5
SR 1 dBm -48 -48 Tone 1 Power
SR 3 dBm -46 -46
SR 1 MHz +4.9 -4.9 +4.9 -4.9 Tone 2 Offset from Carrier SR 3 MHz +9.7 -9.7 +9.7 -9.7
SR 1 dBm -48 -48 Tone 2 Power
SR 3 dBm -46 -46
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
When operating a Spreading Rate 3 system that is overlaid on a Spreading Rate 1 carrier, the Spreading Rate 1 intermodulation tests shall not apply.
Japanese Radio Law currently requires that this test be performed for mobile stations operating in Japan that support Band Class 6 using the test methods described in Table 3.5.3.2-2.
3
3GPP2 C.S0011-A Ballot Resolution Version
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Table 3.5.3.2-4. Test Parameters for Band Class 0 Intermodulation Spurious Response 1
Attenuation (Tests 3 and 4) 2
Parameter Units Test 3 Test 4
Tone 1 Offset from Carrier kHz +900 -900
Tone Power 1 dBm -32
Tone 2 Offset from Carrier kHz +1700 -1700
Tone Power 2 dBm -32
Îor dBm/1.23 MHz -90
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6
3
Table 3.5.3.2-5. Test Parameters for Band Class 0 Intermodulation Spurious Response 4
Attenuation (Tests 5 and 6) 5
Parameter Units Test 5 Test 6
Tone 1 Offset from Carrier kHz +900 -900
Tone Power 1 dBm -21
Tone 2 Offset from Carrier kHz +1700 -1700
Tone Power 2 dBm -21
Îor dBm/1.23 MHz -79
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6
6
3.5.3.3 Minimum Standard 7
The FER in Tests 1, 2, 5, and 6 shall not exceed 1.0% with 95% confidence (see 6.6). 8
The FER in Tests 3 and 4 should not exceed 1.0% with 95% confidence (see 6.6). 9
3.5.4 Adjacent Channel Selectivity 10
This test is applicable to Band Class 6 mobile stations only. 11
3GPP2 C.S0011-A Ballot Resolution Version
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3.5.4.1 Definition 1
Adjacent channel selectivity is a measure of the ability to receive a CDMA signal on the 2
assigned channel frequency in the presence of another CDMA signal that is offset from the 3
center frequency of the assigned channel by ± 2.5 MHz for Spreading Rate 1 or ± 5 MHz for 4
Spreading Rate 3. 5
3.5.4.2 Method of Measurement 6
1. Connect the base station and an interfering modulated signal to the mobile station 7
antenna connector as shown in Figure 6.5.1-4. The modulated interference shall be 8
a signal modulated with a combination of Pilot, Sync, Paging and Traffic Channels 9
as specified in Table 3.5.4.2-1. The source shall be Radio Configuration 3 with full 10
rate traffic channels for Spreading Rate 1 tests, and Radio Configuration 6 with full 11
rate traffic channels for Spreading Rate 3 tests. 12
2. For all tests, Forward Traffic Channel closed loop power control should be disabled 13
in the base station. 14
3. Configure the base station to operate in Band Class 6 and perform steps 4 through 15
9. 16
4. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 17
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 18
and perform steps 7 through 9. 19
5. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 20
up a call using Fundamental Channel Test Mode 1 or 3 or Dedicated Control 21
Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 7 22
through 9. 23
6. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 24
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 25
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 7 and 8. 26
7. Set the test parameters for Test 1 as specified in Table 3.5.4.2-2 and perform step 27
9. 28
8. Set the test parameters for Test 2 as specified in Table 3.5.4.2-2 and perform step 29
9. 30
9. Count, at the base station, the number of frames transmitted and the number of 31
good frames received at the mobile station. 32
33
3GPP2 C.S0011-A Ballot Resolution Version
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Table 3.5.4.2-1. Configuration for Interference Source 1
Channel Type
Number of Channels
Fraction of Power (linear)
Fraction of Power (dB)
Comments
Forward Pilot 1 0.2000 -7.0 Code channel 1280W
Sync 1 0.0471 -13.3 Code channel 6432W ;
always 1/8 rate
Paging 1 0.1882 -7.3 Code channel 641W ;
full rate only
Traffic 6 0.09412 -10.3 Variable code channel assignments; full rate only
2
Table 3.5.4.2-2. Test Parameters for Adjacent Channel Selectivity 3
Parameter Units Tests 1 Tests 2
SR 1 MHz +2.5 -2.5 Adjacent CDMA
Channel Offset from Carrier
SR 3 MHz +5.0 -5.0
dBm/1.23 MHz
-37 (SR 1)
Interference Source, modulated source
dBm / 3.69 MHz
-50 (SR 3)
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
4
3.5.4.3 Minimum Standard 5
The FER in each test shall not exceed 1.0% with 95% confidence (see 6.6). 6
3.5.5 Receiver Blocking Characteristics 7
This test is applicable to Band Class 6 mobile stations only. 8
3GPP2 C.S0011-A Ballot Resolution Version
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3.5.5.1 Definition 1
The receiver blocking characteristic is a measure of the receivers ability to receive a CDMA 2
signal at its assigned channel frequency in the presence of a single tone on frequencies 3
other than those of the adjacent channels, without this unwanted input signal causing a 4
degradation of the performance of the receiver beyond a specified limit. 5
3.5.5.2 Method of Measurement 6
1. Connect the base station and an interfering CW tone to the mobile station antenna 7
connector as shown in Figure 6.5.1-4. 8
2. For all tests, Forward Power Control should be disabled in the base station. 9
3. Configure the base station to operate in Band Class 6. 10
4. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 11
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 12
and perform steps 7 through 15. 13
5. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 14
up a call using Fundamental Test Mode 1 or 3 or Dedicated Control Channel Test 15
Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 7 through 15. 16
6. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 17
up a call using Fundamental Test Mode 7 or Dedicated Control Channel Test Mode 18
7 (see 1.3) with 9600 bps data rate only and perform steps 7 through 15. 19
7. Set the test parameters for Test 1 as specified in Table 3.5.5.2-1 and perform step 20
15. 21
8. Set the test parameters for Test 2 as specified in Table 3.5.5.2-1 and perform step 22
15. 23
9. Set the test parameters for Test 3 as specified in Table 3.5.5.2-1 and perform step 24
15. 25
10. Set the test parameters for Test 4 as specified in Table 3.5.5.2-1 and perform step 26
15. 27
11. Set the test parameters for Test 5 as specified in Table 3.5.5.2-2 and perform steps 28
14 and 15 using the Default CW Tone Power. 29
12. Set the test parameters for Test 6 as specified in Table 3.5.5.2-2 and perform steps 30
14 and 15 using the Default CW Tone Power. 31
13. Set the test parameters for Test 7 as specified in Table 3.5.5.2-2 and perform steps 32
14 and 15 using the Default CW Tone Power. 33
14. Step the CW tone frequency through each inclusive range of frequencies given for 34
the current test in Table 3.5.5.2-2 at 1 MHz intervals and perform step 15. 35
15. Count, at the base station, the number of frames transmitted and the number of 36
good frames received at the mobile station. 37
3GPP2 C.S0011-A Ballot Resolution Version
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16. If spurious responses occurred in tests 6 or 7 repeat steps 15 for each spurious 1
response frequency using the Alternate CW Tone Power given in Table 3.5.5.2-2. 2
3
Table 3.5.5.2-1. Test Parameters for Receiver Blocking Characteristics (In-Band) 4
Parameter Units Test 1 Tests 2 Tests 3 Tests 4
CW Tone Offset SR 1 kHz +5000 -5000 +7500 -7500
from Carrier SR 3 kHz +10000 -10000 +15000 -15000
CW Tone Power dBm -56 -44
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
5
Table 3.5.5.2-2. Test Parameters for Receiver Blocking Characteristics (Out-Of-Band) 6
Parameter Units Test 5 Test 6 Test 7
CW Tone Frequency
MHz 2051 2095
2185 2230
2026 2050
2231 2255
1 2025
2255 12750
Default
CW Tone Power dBm -44 -30 -15
Alternate
CW Tone Power dBm -44 -44
Îor dBm/ 1.23 MHz
-101
orc
IEPilot
dB -7
orc
IE Traffic
dB -15.6 (SR 1) -20.6 (SR 3)
For the case of a Spreading Rate 3 system, Îor is the received power on each carrier.
7
3GPP2 C.S0011-A Ballot Resolution Version
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3.5.5.3 Minimum Standard 1
The FER in tests 1 through 5 shall not exceed 10% with 90% confidence (see 6.6). With up 2
to twenty-four (24) exceptions at spurious response frequencies, the FER in tests 6 and 7 3
shall not exceed 10% with 90% confidence (see 6.6). In case of such spurious response 4
exception(s) in tests 6 or 7, the FER shall not exceed 10% with 90% confidence (see 6.6) 5
when using the Alternate CW Tone Power for interference at the one or more spurious 6
response frequencies. 7
3.6 Limitations on Emissions 8
3.6.1 Conducted Spurious Emissions 9
3.6.1.1 Definition 10
Conducted spurious emissions are spurious emissions generated or amplified in a receiver 11
that appear at the mobile station antenna connector. 12
3.6.1.2 Method of Measurement 13
1. Connect a spectrum analyzer (or other suitable test equipment) to the mobile 14
station antenna connector. 15
2. For each band class that the mobile station supports, configure the mobile station 16
to operate in that band class and perform steps 3 and 4. 17
3. Enable the mobile station receiver for CDMA-only mode, so that the mobile station 18
continuously cycles between the System Determination Substate and the Pilot 19
Channel Acquisition Substate of the Mobile Station Initialization State. Since there is 20
no Forward CDMA Channel for this configuration, the mobile station should not 21
pass the Pilot Channel Acquisition Substate. 22
4. For band classes 0, 1, 2, 3, 4, 5, 7, 8 and 9, sweep the spectrum analyzer over a 23
frequency range from the lowest intermediate frequency or lowest oscillator 24
frequency used in the receiver or 1 MHz, whichever is lowest, to at least 2600 MHz 25
for band classes 0, 2, 5, 7 and 9, 3 GHz for Band Class 3 or at least 6 GHz for band 26
classes 1, 4 and 8, and measure the spurious emission levels. For Band Class 6, 27
sweep the spectrum analyzer over a frequency range from 30 MHz to at least 12.75 28
GHz and measure the spurious emissions levels. 29
3.6.1.3 Minimum Standard 30
The conducted spurious emissions for a mobile station shall be: 31
1. Less than -76 dBm for band classes 0, 1, 2, 4, 5, 6, 7, 8 and 9, or 81 dBm for 32
Band Class 3, measured in a 1 MHz resolution bandwidth at the mobile station 33
antenna connector, for frequencies within the mobile station receive band (see 3.1) 34
associated with each band class that the mobile station supports. 35
2. Less than -61 dBm, measured in a 1 MHz resolution bandwidth at the mobile 36
station antenna connector, for frequencies within the mobile station transmit band 37
(see 3.1) associated with each band class that the mobile station supports. 38
3GPP2 C.S0011-A Ballot Resolution Version
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3. Less than 57 dBm for Band Class 6, measured in a 100 kHz resolution bandwidth 1
at the mobile station antenna connector (see 3.1), for frequencies from 30 MHz to 1 2
GHz. 3
4. Less than -47 dBm for band classes 0, 1, 2, 4, 5, 7, 8 and 9, or 54 dBm for Band 4
Class 3, measured in a 30 kHz resolution bandwidth at the mobile station antenna 5
connector (see 3.1), for all other frequencies. Less than 47 dBm for Band Class 6, 6
measured in a 1 MHz resolution bandwidth at the mobile station antenna 7
connector (see 3.1), for all other frequencies in the range from 1 GHz to 12.75 GHz. 8
Current region-specific radio regulation rules shall also apply. 9
For example, a Band Class 6 mobile station operating under Japan regional requirements 10
shall limit conducted emissions to: 11
1) less than -41 dBm, measured in a 300 kHz resolution bandwidth at the mobile 12
station antenna connector, for frequencies within the PHS band from 1893.5 to 13
1919.6 MHz, and 14
2) less than 81dBm, measured in 1MHz resolution bandwidth at the mobile station 15
antenna connector (see 3.1), for frequencies within the Japan Band Class 6 mobile 16
station receive band (see 3.1). 17
3.6.2 Radiated Spurious Emissions 18
3.6.2.1 Definition 19
Radiated spurious emissions are those spurious emissions generated or amplified in a 20
receiver and radiated by the antenna, housing and all power, control, and audio leads 21
connected to the receiver. 22
3.6.2.2 Method of Measurement 23
1. For each band class that the mobile station supports, configure the mobile station 24
to operate in that band class and perform steps 2 and 3. 25
2. Enable the mobile station receiver for CDMA-only mode, so that the mobile station 26
continuously cycles between the System Determination Substate and the Pilot 27
Channel Acquisition Substate of the Mobile Station Initialization State. Since there is 28
no Forward CDMA Channel, the mobile station should not pass the Pilot Channel 29
Acquisition Substate. 30
3. Use the measurement procedure defined in Section 2 to measure the radiated 31
spurious emissions of the mobile station receiver. 32
3.6.2.3 Minimum Standard 33
The radiated spurious power levels from the receiver, when measured using the procedure 34
in Section 2, shall not exceed the levels specified in Tables 3.6.2.3-1 and 3.6.2.3-2. 35
36
3GPP2 C.S0011-A Ballot Resolution Version
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Table 3.6.2.3-1. Maximum Allowable Radiated Spurious Emissions 1
for Band Classes 0, 1, and 7 2
Frequency Range Maximum Allowable EIRP
30 to 88 MHz -55 dBm
88 to 216 MHz -52 dBm
216 to 960 MHz -49 dBm
960 to 2200 MHz -41 dBm
3
Table 3.6.2.3-2. Maximum Allowable Radiated Spurious Emissions 4
for Band Classes 2, 3, 4, 5, 6, 8, and 9 5
Frequency Range Maximum Allowable EIRP
25 to 70 MHz -45 dBm
70 to 130 MHz -41 dBm
130 to 174 MHz -41 to -32 dBm*
174 to 260 MHz -32 dBm
260 to 470 MHz -32 to -26 dBm*
470 to 1000 MHz (band classes 2, 5, and 9)
-21 dBm
470 to 2200 MHz (band classes 4, 6 and 8)
-21 dBm
470 to 3000 MHz (Band Class 3)
-21 dBm
1 GHz to 12.75 GHz (Band Class 6)
-6 dBm
*Interpolate linearly on a log frequency scale. 6
7
Current region-specific radio regulation rules shall also apply. 8
For example, a Band Class 7 base station operating under US regional requirements shall 9
limit radiated spurious emissions to less than 70 dBW/MHz EIRP in the GPS band from 10
1559 to 1610 MHz. 11
3GPP2 C.S0011-A Ballot Resolution Version
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3.7 Supervision 1
3.7.1 Paging Channel 2
3.7.1.1 Definition 3
When in the System Access State, the mobile station shall monitor the Paging Channel. The 4
mobile station shall reset a timer for T40m seconds whenever a valid message is received on 5
the Paging Channel, whether addressed to the mobile station or not. If the timer expires, 6
the mobile station shall stop transmitting access attempts. This test verifies the mobile 7
station supervision of the Paging Channel when it is in the System Access State. 8
3.7.1.2 Method of Measurement 9
1. Connect the base station to the mobile station antenna connector as shown in . The 10
AWGN generator and the interference generator are not applicable in this test. 11
2. For each band class that the mobile station supports, configure the mobile station 12
to operate in that band class and perform steps 3 through 8. 13
3. Set the base station to ignore all access attempts. 14
4. Set the test parameters as specified in Table 3.7.1.2-1. 15
5. Set the following parameters of the Access Parameters Message to the value 16
specified below: 17
18
Parameter Value (Decimal)
NUM_STEP 15 (16 probes/sequence)
MAX_RSP_SEQ 15 (15 sequences)
19
6. Send a page to the mobile station. 20
7. Wait for two seconds and disable the Paging Channel. 21
8. Monitor the mobile station output power. 22
23
Table 3.7.1.2-1. Test Parameters for Supervision of Paging Channel 24
Parameter Units Value
Îor dBm/1.23 MHz -55
orc
IEPilot
dB -7
orc
IEPaging
dB -16
25
3GPP2 C.S0011-A Ballot Resolution Version
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3.7.1.3 Minimum Standard 1
The mobile station shall transmit access attempts as a response to the page. The mobile 2
station shall stop transmitting access attempts T40m seconds after the Paging Channel is 3
disabled. 4
3.7.2 Forward Traffic Channel 5
This test shall be performed on the Forward Fundamental Channel and the Forward 6
Dedicated Control Channel if they are supported. The test shall be performed separately for 7
each supported channel. 8
3.7.2.1 Definition 9
When in the Mobile Station Control on the Traffic Channel State, the mobile station shall 10
continuously monitor the Forward Traffic Channel, except: 11
During a PUF probe in which it transmits on a PUF target frequency (see Section 12
2.6.4.1.7 of [6]), 13
During a search of pilots on a CDMA Candidate Frequency (see Section 2.6.6.2.8.3 14
of [6]), 15
During a search of analog frequencies (see Section 2.6.6.2.10 of [6]). 16
The mobile station shall monitor the physical channel corresponding to FPC_PRI_CHANs. 17
If the mobile station receives N2m frames with insufficient signal quality (e.g. bad frames) 18
on the physical channel corresponding to FPC_PRI_CHANs, it shall disable its transmitter. 19
Thereafter, if the mobile station receives N3m frames with sufficient signal quality (e.g. good 20
frames) on the physical channel corresponding to FPC_PRI_CHANs, then the mobile station 21
should re-enable its transmitter. 22
The mobile station shall establish a Forward Traffic Channel fade timer. The timer shall be 23
enabled when the mobile station first enables its transmitter when in the Traffic Channel 24
Initialization Substate of the Mobile Station Control on the Traffic Channel State. The fade 25
timer shall be reset for T5m seconds whenever the mobile station receives N3m frames with 26
sufficient signal quality (e.g. good frames) on the physical channel corresponding to 27
FPC_PRI_CHANs. The mobile station shall disable the fade timer when it tunes to a PUF 28
target frequency, and shall re-enable the fade timer at the end of the PUF probe. If the timer 29
expires, the mobile station shall disable its transmitter and declare a loss of the Forward 30
Traffic Channel. 31
The mobile station also enables, disables, and resets the fade timer when it performs a hard 32
handoff or a periodic search, as described in Sections 2.6.6.2.8 and 2.6.6.2.10 of [6]. 33
The mobile station shall not disable its transmitter in the case that it is not receiving data 34
but is receiving continuous periods of sufficient signal quality power control bits on the 35
Forward Dedicated Control Channel. 36
Test 1 verifies that the mobile station monitoring the Forward Traffic Channel disables its 37
transmitter after receiving N2m frames with insufficient signal quality. 38
3GPP2 C.S0011-A Ballot Resolution Version
3-102
Test 2 verifies that the mobile station monitoring the Forward Traffic Channel disables its 1
transmitter and declares a loss of the Forward Traffic Channel after not receiving N3m 2
frames with sufficient signal quality for a period of T5m seconds. 3
Test 3 verifies that the mobile station does not disable its transmitter while receiving a 4
period of 2 seconds with sufficient signal quality with power control bits only, but no data. 5
3.7.2.2 Method of Measurement 6
1. Connect the base station to the mobile station antenna connector as shown in 7
Figure 6.5.1-4. The AWGN generator and the interference generator are not 8
applicable in this test. 9
2. For each band class that the mobile station supports, configure the mobile station 10
to operate in that band class and perform steps 3 through 7. 11
3. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 12
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 13
and perform steps 8 through 15. 14
4. If the mobile station supports the Fundamental Channel and demodulation of 15
Radio Configuration 3, 4, or 5, set up a call using Fundamental Channel Test Mode 16
1 or 3 (see 1.3) with 9600 bps data rate only and perform steps 8 through 19. 17
5. If the mobile station supports the Dedicated Control Channel and demodulation of 18
Radio Configuration 3, 4, or 5, set up a call using Dedicated Control Channel Test 19
Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 8 through 18. 20
6. If the mobile station supports the Fundamental Channel and demodulation of 21
Radio Configuration 6, 7, 8, or 9, set up a call using Fundamental Channel Test 22
Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 8 through 15. 23
7. If the mobile station supports the Dedicated Control Channel and demodulation of 24
Radio Configuration 6, 7, 8, or 9, set up a call using Dedicated Control Channel 25
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 8 through 19. 26
8. Set the base station so as to not drop a call. 27
9. Set the test parameters as specified in Table 3.7.2.2-1. 28
10. Send the Forward Fundamental Channel with 9600 bps data rate only or the 29
Forward Dedicated Control Channel with power control bits but no data (i.e. DCCH 30
frame activity = 0%). 31
11. Disable the transmission on the Forward Fundamental Channel or the Forward 32
Dedicated Control Channel starting at a frame boundary for exactly N2m × 0.02 33
seconds. 34
12. Monitor the mobile station output power (Test 1). 35
13. Set the test parameters as specified in Table 3.7.2.2-1. 36
14. Disable and enable, on an alternating frame-by-frame basis, the transmission of 37
the Forward Fundamental Channel or the Forward Dedicated Control Channel 38
3GPP2 C.S0011-A Ballot Resolution Version
3-103
frames for at least T5m seconds starting at the beginning of the first disabled 1
Forward Traffic Channel frame. 2
15. Monitor the mobile station output power (Test 2). 3
16. Set up a call using the same Dedicated Control Channel test mode used in Test 1 4
and 2. 5
17. Set the test parameters as specified in Table 3.7.2.2-1. 6
18. Send 100 frames with power control bits only, but no data on the Forward 7
Dedicated Control Channel (i.e. frame activity = 0%), starting at a Forward Traffic 8
Channel frame boundary. 9
19. Monitor the mobile station output power (Test 3). 10
11
Table 3.7.2.2-1. Test Parameters for Supervision of Forward Traffic Channel 12
Parameter Units Value
Îor dBm/1.23 MHz -75
orc
IEPilot
dB -7
orc
IE Traffic
dB -16
13
3.7.2.3 Minimum Standard 14
Test 1: 15
The mobile station shall disable its transmitter N2m × 0.02 + 0.02 seconds after the 16
Forward Traffic Channel is disabled. The mobile station shall re-enable its transmitter N3m 17
× 0.02 + 0.02 seconds after the start of the first re-enabled Forward Traffic Channel frame. 18
Test 2: 19
The mobile station shall disable its transmitter T5m + 0.02 seconds after the first Forward 20
Traffic Channel frame has been disabled. The mobile station shall not re-enable its 21
transmitter. 22
Test 3: 23
The mobile station shall not disable its transmitter during the 2 seconds. 24
25
3GPP2 C.S0011-A Ballot Resolution Version
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1
No text. 2
3GPP2 C.S0011-A Ballot Resolution Version
4-1
4 CDMA TRANSMITTER MINIMUM STANDARDS 1
4.1 Frequency Accuracy 2
4.1.1 Definition 3
Frequency accuracy is the ability of a mobile station transmitter to transmit at an assigned 4
carrier frequency. 5
4.1.2 Method of Measurement 6
The method of measurement specified in 4.3.4.2 may be used to perform this test. 7
4.1.3 Minimum Standard 8
The mobile station output carrier frequency while transmitting in Band Class 0 shall be 9
within ±300 Hz of 45 MHz below the carrier frequency of the Forward CDMA Channel. 10
The mobile station output carrier frequency while transmitting in Band Class 1 shall be 11
within ±150 Hz of 80 MHz below the carrier frequency of the Forward CDMA Channel. 12
The mobile station output carrier frequency while transmitting in Band Class 2 shall be 13
within ±300 Hz of 45 MHz below the carrier frequency of the Forward CDMA Channel. 14
The mobile station output carrier frequency while transmitting in Band Class 3 shall be 15
within ±300 Hz of 55 MHz above the carrier frequency of the Forward CDMA Channel. 16
The mobile station output carrier frequency while transmitting in Band Class 4 shall be 17
within ±150 Hz of 90 MHz below the carrier frequency of the Forward CDMA Channel. 18
The mobile station output carrier frequency while transmitting in Band Class 5 shall be 19
within ±300 Hz of 10 MHz below the carrier frequency of the Forward CDMA Channel. 20
The mobile station output carrier frequency while transmitting in Band Class 6 shall be 21
within ±150 Hz of 190 MHz below the carrier frequency of the Forward CDMA Channel. 22
The mobile station output carrier frequency while transmitting in Band Class 7 shall be 23
within ±300 Hz of 30 MHz below the carrier frequency of the Forward CDMA Channel. 24
The mobile station output carrier frequency while transmitting in Band Class 8 shall be 25
within ±150 Hz of 95 MHz below the carrier frequency of the Forward CDMA Channel. 26
The mobile station output carrier frequency while transmitting in Band Class 9 shall be 27
within ±300 Hz of 45 MHz below the carrier frequency of the Forward CDMA Channel. 28
4.2 Handoff 29
4.2.1 CDMA to CDMA Hard Handoff 30
4.2.1.1 Definition 31
The base station directs the mobile station to perform a CDMA to CDMA hard handoff by 32
sending a Universal Handoff Direction Message in which the mobile station is transitioned 33
3GPP2 C.S0011-A Ballot Resolution Version
4-2
between disjoint sets of base stations, different frequency assignments, or different frame 1
offsets. Hard handoff is characterized by a temporary disconnection of the Traffic Channel. 2
This test measures the time to execute a CDMA to CDMA hard handoff between Traffic 3
Channels belonging to different base stations (different pilot PN offset indices) with different 4
CDMA frequency assignments in the same band class. This test also verifies that the mobile 5
station disables its transmitter before changing frequency. 6
4.2.1.2 Method of Measurement 7
1. Connect two base stations to the mobile station antenna connector as shown in 8
Figure 6.5.1-3. The AWGN generator is not applicable in this test. The Forward 9
Channel from base station 1 has an arbitrary pilot PN offset index P1, a CDMA 10
frequency assignment f1(any valid value), and is called Channel 1. The Forward 11
Channel from base station 2 has an arbitrary pilot PN offset index P2, a CDMA 12
frequency assignment f2 (any valid value other than f1in the same band class), and 13
is called Channel 2. Channel 2 shall be available at the action time specified in the 14
Universal Handoff Direction Message sent in step 7. 15
2. For each band class that the mobile station supports, configure the mobile station 16
to operate in that band class and perform steps 3 through 8. 17
3. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 18
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 19
and perform steps 6 through 8. 20
4. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 21
up a call using Fundamental Channel Test Mode 3 or Dedicated Control Channel 22
Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 6 through 8. 23
5. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 24
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 25
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 6 through 8. 26
6. Set the test parameters as specified in Table 4.2.1.2-1. 27
7. Send a Universal Handoff Direction Message to the mobile station to set an explicit 28
action time and the following parameters: 29
30
Parameter Value (Decimal)
USE_TIME 1 (use action time)
PILOT_PN P2
FREQ_INCL 1 (frequency included)
CDMA_FREQ f2
31
8. Measure T1, the time elapsed from the action time to the instant the mobile station 32
transmit power, as measured at the mobile station antenna connector, on the old 33
3GPP2 C.S0011-A Ballot Resolution Version
4-3
CDMA frequency assignment drops below -61 dBm/MHz. Measure T2, the time 1
elapsed from the action time to the instant the mobile station transmitter is 2
enabled on the new CDMA frequency assignment. 3
4
Table 4.2.1.2-1. Test Parameters for CDMA to CDMA Hard Handoff 5
Parameter Unit Channel 1 Channel 2
Îor dBm/1.23 MHz -75 -75
orc
IEPilot
dB -7 -7
orc
IE Traffic
dB -7.4 -7.4
6
4.2.1.3 Minimum Standard 7
The mobile station transmit power shall remain under open loop and closed loop power 8
control until the action time. T1 shall be less than 2 ms. 9
T2 shall be less than T61m + (N11m + 2) × 20 ms = 140 ms. 10
4.2.2 Transmit Power after Hard Handoff 11
4.2.2.1 Definition 12
Mobile Station output power is given by the following equation: 13
Pout = offset power Pin + NOM_PWR 16 × NOM_PWR_EXT + INIT_PWR 14
1. Configure the base station so that the mobile station uses the Spreading Rate 3 5
Enhanced Access Channel. 6
2. Connect the base station to the mobile station antenna connector as shown in 7
Figure 6.5.1-4. The AWGN generator and the interference generator are not 8
applicable in this test. 9
3. For each band class that the mobile station supports, configure the mobile station 10
to operate in that band class and perform steps 4 through 9. 11
4. Set the parameter values in the Enhanced Access Parameters Message to the values 12
specified below. 13
14
3GPP2 C.S0011-A Ballot Resolution Version
4-19
Parameter Value (Decimal)
REACH_RATE_MODE 0 (9600 bps, 20 ms frame size)
REACH_MODE 0 (Basic Access Mode - no CACH or CPCCH)
EACH_PREAMBLE_NUM_FRAC 0 (no preamble)
EACH _PREAMBLE_ADD_DURATION 0 (no additional preamble)
EACH_MAX_RSP_SEQ 1 (1 sequence)
1
5. Set the test parameter for Test 7 as specified in Table 4.4.1.2.3-1 and perform steps 2
8 and 9. 3
6. Set the test parameter for Test 8 as specified in Table 4.4.1.2.3-1 and perform steps 4
8 and 9. 5
7. Set the test parameter for Test 9 as specified in Table 4.4.1.2.3-1 and perform steps 6
8 and 9. 7
8. Send a page to the mobile station. 8
9. Measure the output power of the mobile station at the antenna connector during 9
transmission of a probe. 10
11
3GPP2 C.S0011-A Ballot Resolution Version
4-20
Table 4.4.1.2.3-1. Test Parameter of Îor for Range of Open Loop Output Power for the 1
Spreading Rate 3 Enhanced Access Channel 2
Band Class
Mobile Station Class
Unit Test 7 Test 8 Test 9
Class I dBm -20 -60 -98.0
0, 7, and 9
Class II dBm -20 -60 -93.3
Class III dBm -20 -60 -88.5
Class I dBm -20 -60 -98.0
Class II dBm -20 -60 -92.0
1, 4, 6, and 8
Class III dBm -20 -60 -86.3
Class IV dBm -20 -60 -81.1
Class V dBm -20 -60 -76.0
Class II dBm -20 -60 -98.0
2 Class III dBm -20 -60 -93.3
Class IV dBm -20 -60 -88.5
Class I dBm -20 -60 -94.7
5 Class II dBm -20 -60 -93.3
Class III dBm -20 -60 -88.5
Class IV dBm -20 -60 -83.1
3
4.4.1.3 Minimum Standard 4
If the mobile station supports the Access Channel, the mobile station output power shall 5
satisfy the range specified in Table 4.4.1.3-1. 6
If the mobile station supports the Spreading Rate 1 Enhanced Access Channel, the mobile 7
station output power shall satisfy the range specified in Table 4.4.1.3-2. 8
If the mobile station supports the Spreading Rate 3 Enhanced Access Channel, the mobile 9
station output power shall satisfy the range specified in Table 4.4.1.3-3. 10
11
3GPP2 C.S0011-A Ballot Resolution Version
4-21
Table 4.4.1.3-1. Minimum Standards for Range of Open Loop Output Power for the 1
Access Channel 2
Band Class
Mobile Station Class
Units Test 1 Test 2 Test 3
Class I dBm -48 ± 9.5 -8 ± 9.5 27 ± 9.5
0, 3, 7, and 9
Class II dBm -48 ± 9.5 -8 ± 9.5 24 ± 9.5
Class III dBm -48 ± 9.5 -8 ± 9.5 20 ± 9.5
Class I dBm -51 ± 9.5 -11 ± 9.5 24 + 9/- 9.5
Class II dBm -51 ± 9.5 -11 ± 9.5 20 ± 9.5
1, 4, 6, and 8
Class III dBm -51 ± 9.5 -11 ± 9.5 15 ± 9.5
Class IV dBm -51 ± 9.5 -11 ± 9.5 10 ± 9.5
Class V dBm -51 ± 9.5 -11 ± 9.5 5 ± 9.5
Class II dBm -48 ± 9.5 -8 ± 9.5 27 ± 9.5
Class III dBm -48 ± 9.5 -8 ± 9.5 24 ± 9.5
2
Class IV dBm -48 ± 9.5 -8 ± 9.5 20 ± 9.5
Class I dBm -48 ± 9.5 -8 ± 9.5 25 ± 9.5
Class II dBm -48 ± 9.5 -8 ± 9.5 24 ± 9.5
Class III dBm -48 ± 9.5 -8 ± 9.5 20 ± 9.5
5
Class IV dBm -48 ± 9.5 -8 ± 9.5 15 ± 9.5
3
3GPP2 C.S0011-A Ballot Resolution Version
4-22
Table 4.4.1.3-2. Minimum Standards for Range of Open Loop Output Power for the 1
Spreading Rate 1 Enhanced Access Channel 2
Band Class
Mobile Station Class
Units Test 4 Test 5 Test 6
Class I dBm -51.2 ± 9.5 -11.2 ± 9.5 23.8 ± 9.5
0, 3, 7, and 9
Class II dBm -51.2 ± 9.5 -11.2 ± 9.5 20.8 ± 9.5
Class III dBm -51.2 ± 9.5 -11.2 ± 9.5 16.8 ± 9.5
Class I dBm -54.2 ± 9.5 -14.2 ± 9.5 20.8 ± 9.5
Class II dBm -54.2 ± 9.5 -14.2 ± 9.5 16.8 ± 9.5
1, 4, 6, and 8
Class III dBm -54.2 ± 9.5 -14.2 ± 9.5 11.8 ± 9.5
Class IV dBm -54.2 ± 9.5 -14.2 ± 9.5 6.8 ± 9.5
Class V dBm -54.2 ± 9.5 -14.2 ± 9.5 1.8 ± 9.5
Class II dBm -51.2 ± 9.5 -11.2 ± 9.5 23.8 ± 9.5
Class III dBm -51.2 ± 9.5 -11.2 ± 9.5 20.8 ± 9.5
2
Class IV dBm -51.2 ± 9.5 -11.2 ± 9.5 16.8 ± 9.5
Class I dBm -51.2 ± 9.5 -11.2 ± 9.5 21.8 ± 9.5
Class II dBm -51.2 ± 9.5 -11.2 ± 9.5 20.8 ± 9.5
Class III dBm -51.2 ± 9.5 -11.2 ± 9.5 16.8 ± 9.5
5
Class IV dBm -51.2 ± 9.5 -11.2 ± 9.5 11.8 ± 9.5
3
3GPP2 C.S0011-A Ballot Resolution Version
4-23
Table 4.4.1.3-3. Minimum Standards for Range of Open Loop Output Power for the 1
Spreading Rate 3 Enhanced Access Channel 2
Band Class
Mobile Station Class
Units Test 7 Test 8 Test 9
Class I dBm -51.2 ± 9.5 -11.2 ± 9.5 23.8 ± 9.5
0, 7, and 9
Class II dBm -51.2 ± 9.5 -11.2 ± 9.5 20.8 ± 9.5
Class III dBm -51.2 ± 9.5 -11.2 ± 9.5 16.8 ± 9.5
Class I dBm -54.2 ± 9.5 -14.2 ± 9.5 20.8 ± 9.5
Class II dBm -54.2 ± 9.5 -14.2 ± 9.5 16.8 ± 9.5
1, 4, 6, and 8
Class III dBm -54.2 ± 9.5 -14.2 ± 9.5 11.8 ± 9.5
Class IV dBm -54.2 ± 9.5 -14.2 ± 9.5 6.8 ± 9.5
Class V dBm -54.2 ± 9.5 -14.2 ± 9.5 1.8 ± 9.5
Class II dBm -51.2 ± 9.5 -11.2 ± 9.5 23.8 ± 9.5
Class III dBm -51.2 ± 9.5 -11.2 ± 9.5 20.8 ± 9.5
2
Class IV dBm -51.2 ± 9.5 -11.2 ± 9.5 16.8 ± 9.5
Class I dBm -51.2 ± 9.5 -11.2 ± 9.5 21.8 ± 9.5
Class II dBm -51.2 ± 9.5 -11.2 ± 9.5 20.8 ± 9.5
Class III dBm -51.2 ± 9.5 -11.2 ± 9.5 16.8 ± 9.5
5
Class IV dBm -51.2 ± 9.5 -11.2 ± 9.5 11.8 ± 9.5
3
4.4.2 Time Response of Open Loop Power Control 4
4.4.2.1 Definition 5
Following a step change in the mean input power, the mean output power of the mobile 6
station changes as a result of the open loop power control. This test measures the open loop 7
power control time response to a step change in the mean input power. 8
4.4.2.2 Method of Measurement 9
1. Connect the base station to the mobile station antenna connector as shown in 10
Figure 6.5.1-4. The AWGN generator and the interference generator are not 11
applicable in this test. 12
2. For each band class that the mobile station supports, configure the mobile station 13
to operate in that band class and perform steps 3 through 11. 14
3. If the mobile station supports demodulation of Radio Configuration 1 or 2, set up a 15
call using Fundamental Channel Test Mode 1 (see 1.3) with 9600 bps data rate only 16
and perform steps 6 through 11. 17
3GPP2 C.S0011-A Ballot Resolution Version
4-24
4. If the mobile station supports demodulation of Radio Configuration 3, 4, or 5, set 1
up a call using Fundamental Channel Test Mode 3 or Dedicated Control Channel 2
Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 6 through 11. 3
5. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 4
up a call using Fundamental Channel Test Mode 7 or Dedicated Control Channel 5
Test Mode 7 (see 1.3) with 9600 bps data rate only and perform steps 6 through 11. 6
6. Set the test parameters as specified in Table 4.4.2.2-1. 7
7. Send alternating 0 and 1 power control bits on the Forward Power Control 8
Subchannel. 9
8. Change the input power by a step of +20 dB and measure the transmitted output 10
power as a function of time after the step change for 100 ms. 11
9. Change the input power by a step of -20 dB and measure the transmitted output 12
power as a function of time after the step change for 100 ms. 13
10. Change the input power by a step of -20 dB and measure the transmitted output 14
power as a function of time after the step change for 100 ms. 15
11. Change the input power by a step of +20 dB and measure the transmitted output 16
power as a function of time after the step change for 100 ms. 17
18
Table 4.4.2.2-1. Test Parameters for Time Response of Open Loop Power Control 19
Parameter Units Value
Îor dBm/1.23 MHz -60
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4
20
4.4.2.3 Minimum Standard 21
Following a step change in mean input power, ∆Pin, the mean output power of the mobile 22
station shall transition to its final value in a direction opposite in sign to ∆Pin, with 23
magnitude contained between mask limits5 defined by: 24
(a) upper limit: 25
for 0 < t < 24 ms: max [1.2 × |∆Pin| × (t/24), |∆Pin| × (t/24) + 2.0 dB] + 1.5 dB, 26
5 The mask limits can be approximated by a piece-wise linear approximation. The mask limits allow for the effect of alternating closed loop power control bits.
3GPP2 C.S0011-A Ballot Resolution Version
4-25
for t ≥ 24 ms: max [1.2 × |∆Pin|, |∆Pin| + 0.5 dB] + 1.5 dB; 1
(b) lower limit: 2
for t > 0: max [0.8 × |∆Pin| × [1 - e(1.25 - t)/36] - 2.0 dB, 0] - 1 dB; 3
where t is expressed in units of milliseconds, ∆Pin is expressed in units of dB, and max [x,y] 4
is the maximum of x and y. Figure 4.4.2.3-1 shows the limits for ∆Pin = 20 dB. The absolute 5
value of the change in mean output power due to open loop power control shall be a 6
monotonically increasing function of time. If the change in mean output power consists of 7
discrete increments, no single increment due to open loop power control shall exceed 1.2 8
dB. 9
10
-
0
5
10
15
20
25
30
0 10 20 30 40 50 60 70 80 90 100
t (ms)
OutputPowerChange[dB]
11
12
Figure 4.4.2.3-1. Upper and Lower Limits for Open Loop Power Control Step Response 13
for ∆∆∆∆Pin = 20 dB 14
15
4.4.3 Access Probe Output Power 16
These tests shall be performed for each of the Access Channel, Spreading Rate 1 Enhanced 17
Access Channel and Spreading Rate 3 Enhanced Access Channel that the mobile station 18
supports. These tests shall be performed for each band class supported by the mobile 19
station. 20
4.4.3.1 Definition 21
This test verifies the following Access Channel and Enhanced Access Channel parameters: 22
nominal power offset, initial power offset, power increment between consecutive probes, 23
number of access probes in one probe sequence, and the number of probe sequences in one 24
mobile station page response access attempt. 25
3GPP2 C.S0011-A Ballot Resolution Version
4-26
4.4.3.2 Method of Measurement 1
4.4.3.2.1 Access Channel Probe Acquisition 2
1. Connect the base station to the mobile station antenna connector as shown in 3
Figure 6.5.1-4. The AWGN generator and the interference generator are not 4
applicable in this test. 5
2. For each band class that the mobile station supports, configure the mobile station 6
to operate in that band class and perform steps 3 through 8. 7
3. Set Îor to -75 dBm /1.23 MHz. 8
4. Set the parameter MAX_RSP_SEQ in the Access Parameters Message to one. 9
5. Set the base station to ignore all access attempts. 10
6. Send a page to the mobile station on the Paging Channel. 11
7. Measure the mobile station output power for each probe at the antenna connector. 12
8. Change the parameter values in the Access Parameters Message to the values 13
1. Connect the base station to the mobile station antenna connector as shown in 18
Figure 6.5.1-4. The AWGN generator and the interference generator are not 19
applicable in this test. 20
2. For each Enhanced Access Channel spreading rate supported by the mobile station, 21
perform steps 3 through 9. 22
3. For each band class that the mobile station supports, configure the mobile station 23
to operate in that band class and perform steps 4 through 9. 24
4. Set Îor to -75 dBm /1.23 MHz. 25
5. Set the parameter MAX_RSP_SEQ in the Enhanced Access Parameters Message to 26
one. 27
6. Set the base station to ignore all access attempts. 28
7. Send a page to the mobile station on the Forward Common Control Channel. 29
3GPP2 C.S0011-A Ballot Resolution Version
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8. Measure the mobile station output power for each Enhanced Access Channel 1
access probe at the antenna connector. 2
9. Change the parameter values in the Enhanced Access Parameters Message to the 3
values specified below. Repeat steps 6 through 8. 4
5
Parameter Value (Decimal)
EACH_NOM_PWR 3 (3 dB)
EACH_INIT_PWR 3 (3 dB)
EACH_PWR_STEP 1 (1 dB/step)
EACH_NUM_STEP 4 (5 probes/sequence)
MAX_RSP_SEQ 3 (3 sequences)
6
4.4.3.3 Minimum Standard 7
For each Access Channel, Spreading Rate 1 Enhanced Access Channel and Spreading Rate 8
3 Enhanced Access Channel supported by the mobile station, the mobile station shall meet 9
the following requirements: 10
In the first access attempt: 11
(a) The power of all access probes shall be within a range of ±1 dB of each other. 12
(b) The number of access probes in an access probe sequence shall be five. 13
(c) There shall be one access probe sequence in the page response access attempt. 14
In the second access attempt: 15
(a) The power of the first access probe of each access probe sequence shall be 6 ± 1.2 dB 16
above the power of the access probes in the first access scenario. 17
(b) The power increment between consecutive access probes in each access probe 18
sequence shall be 1 ± 0.5 dB. 19
(c) The number of access probes in each access probe sequence shall be five. 20
(d) The number of access probe sequences in the page response access attempt shall be 21
three. 22
(e) The Access Channel probes shall be randomized as specified in Section 2.1.1.2.2 of 23
[5] and Section 2.2.4.4.2.1.4 of [6]. 24
4.4.4 Range of Closed Loop Power Control 25
4.4.4.1 Definition 26
The mobile station provides a closed loop adjustment to its open loop estimate. Adjustments 27
are made in response to valid received power control bits. The range of the adjustment is 28
defined by the difference between the maximum mobile station output power and the open 29
3GPP2 C.S0011-A Ballot Resolution Version
4-28
loop estimate, and the difference between the minimum mobile station output power and 1
the open loop estimate. 2
4.4.4.2 Method of Measurement 3
1. Connect the base station to the mobile station antenna connector as shown in 4
Figure 6.5.1-4. The AWGN generator and the interference generator are not 5
applicable in this test. 6
2. Set the power control step size to 1 dB. 7
3. For each band class that the mobile station supports, configure the mobile station 8
to operate in that band class and perform steps 4 through 21. 9
4. If the mobile station supports demodulation of Radio Configuration 1 or 2, perform 10
steps 7 through 21 using Fundamental Channel Test Mode 1 (see 1.3). 11
5. If the mobile station supports the demodulation of Radio Configuration 3, 4, or 5, 12
perform steps 7 through 21 using Fundamental Channel Test Mode 3 or if the 13
Forward Fundamental Channel is not supported, perform steps 7 through 11 using 14
the Dedicated Control Channel Test Mode 3 (see 1.3). 15
6. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, 16
perform steps 7 through 21 using Fundamental Channel Test Mode 7 or if the 17
Forward Fundamental Channel is not supported, perform steps 7 through 11 using 18
the Dedicated Control Channel Test Mode 7 (see 1.3). 19
7. Set up a call using the Fundamental Channel test mode or Dedicated Control 20
Channel test mode (see 1.3) with 9600 bps data rate only. 21
8. Set the attenuation in the Forward CDMA Channel to yield an open loop output 22
power, measured at the mobile station antenna connector, of -15 dBm (Test 1) and 23
perform steps 10 and 11. 24
9. Set the attenuation in the Forward CDMA Channel to yield an open loop output 25
power, measured at the mobile station antenna connector, of 19 dBm (Test 2) and 26
perform steps 10 and 11. 27
10. Transmit alternating 0 and 1 power control bits (the last bit is a 1 bit), followed 28
by 100 consecutive 0 power control bits, followed by 100 consecutive 1 power 29
control bits, and followed by 100 consecutive 0 power control bits. 30
11. Measure the mobile station output power. 31
12. Set up a call using the Fundamental Channel test mode (see 1.3) with 4800 bps 32
data rate only. 33
13. Set the attenuation in the Forward CDMA Channel to yield an open loop output 34
power, measured at the mobile station antenna connector, of -15 dBm when the 35
mobile station transmitter is gated on (Test 3) and perform steps 18 and 19. 36
14. Set up a call using the Fundamental Channel test mode (see 1.3) with 2400 bps 37
data rate only. 38
3GPP2 C.S0011-A Ballot Resolution Version
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15. Set the attenuation in the Forward CDMA Channel to yield an open loop output 1
power, measured at the mobile station antenna connector, of -15 dBm when the 2
mobile station transmitter is gated on (Test 4) and perform steps 18 and 19. 3
16. Set up a call using the Fundamental Channel test mode (see 1.3) with 1200 bps 4
data rate only. 5
17. Set the attenuation in the Forward CDMA Channel to yield an open loop output 6
power, measured at the mobile station antenna connector, of -15 dBm when the 7
mobile station transmitter is gated on (Test 5) and perform steps 18 and 19. 8
18. Transmit alternating 0 and 1 valid power control bits (the last bit is a 1 bit), 9
followed by 100 consecutive 0 valid power control bits, followed by 100 consecutive 10
1 valid power control bits, and followed by 100 consecutive 0 valid power control 11
bits. Set all invalid power control bits to 0. 12
19. Measure the mobile station output power. 13
20. If the mobile station supports 0.5 dB power control step size, set the power control 14
step size to 0.5 dB and perform steps 7 through 17, with the exception of step 9. 15
Tests 6, 7, 8, and 9 are equivalent to Tests 1, 3, 4, and 5, with the exception of step 16
size. 17
21. If the mobile station supports 0.25 dB power control step size, set the power control 18
step size to 0.25 dB and perform steps 7 through 17, with the exception of step 9. 19
Tests 10, 11, 12, and 13 are equivalent to Tests 1, 3, 4, and 5, with the exception of 20
step size. 21
4.4.4.3 Minimum Standard 22
The average rate of change in mean output power requirement specified below applies to 23
mobile station output power up to 3 dB below the lower limit of the maximum output power 24
specified in Table 4.4.5.3-1. 25
Test 1: 26
(a) The closed loop power control range shall be at least ±24 dB around the open loop 27
estimate. 28
(b) The interval from the end of the first valid 1 power control bit after the 100 29
consecutive 0 valid power control bits to the time the mobile station output power 30
starts to decrease shall be no longer than 2.5 ms. 31
(c) The average rate of change in mean output power for 9600 bps data rate shall be 32
greater than 12.8 dB per 20 ms and less than 19.2 dB per 20 ms. 33
(d) Following the reception of any valid power control bit that occurs 2.5 ms after the 34
100 consecutive '0' valid power control bits, the mean output power of the mobile 35
station shall be within 0.3 dB of its final value in less than 500 µs. 36
Test 2: 37
3GPP2 C.S0011-A Ballot Resolution Version
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(a) The interval from the end of the first valid 1 power control bit after the 100 1
consecutive 0 valid power control bits until the time the mobile station output 2
power starts to decrease shall be no longer than 2.5 ms. 3
Test 3: 4
(a) The closed loop power control range shall be at least ±24 dB around the open loop 5
estimate. 6
(b) The interval from the end of the first valid 1 power control bit after the 100 7
consecutive 0 valid power control bits until the time the mobile station output 8
power starts to decrease shall be no longer than 5 ms. 9
(c) The average rate of change in mean output power for 4800 bps data rate shall be 10
greater than 6.4 dB per 20 ms and less than 9.6 dB per 20 ms. 11
Test 4: 12
(a) The closed loop power control range shall be at least ±24 dB around the open loop 13
estimate. 14
(b) The interval from the end of the first valid 1 power control bit after the 100 15
consecutive 0 valid power control bits until the time the mobile station output 16
power starts to decrease shall be no longer than 10 ms. 17
(c) The average rate of change in mean output power for 2400 bps data rate shall be 18
greater than 3.2 dB per 20 ms and less than 4.8 dB per 20 ms. 19
Test 5: 20
(a) The closed loop power control range shall be at least ±24 dB around the open loop 21
estimate. 22
(b) The interval from the end of the first valid 1 power control bit after the 100 23
consecutive 0 valid power control bits until the time the mobile station output 24
power starts to decrease shall be no longer than 20 ms. 25
(c) The average rate of change in mean output power for 1200 bps data rate shall be 26
greater than 1.6 dB per 20 ms and less than 2.4 dB per 20 ms. 27
Test 6: 28
(a) The average rate of change in mean output power for 9600 bps data rate shall be 29
greater than 12 dB per 40 ms and less than 20 dB per 40 ms. 30
(b) Following the reception of any valid power control bit that occurs 2.5 ms after the 31
100 consecutive '0' valid power control bits, the mean output power of the mobile 32
station shall be within 0.15 dB of its final value in less than 500 µs. 33
Test 7: 34
(a) The average rate of change in mean output power for 4800 bps data rate shall be 35
greater than 6.0 dB per 40 ms and less than 10 dB per 40 ms. 36
Test 8: 37
3GPP2 C.S0011-A Ballot Resolution Version
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(a) The average rate of change in mean output power for 2400 bps data rate shall be 1
greater than 3.0 dB per 40 ms and less than 5.0 dB per 40 ms. 2
Test 9: 3
(a) The average rate of change in mean output power for 1200 bps data rate shall be 4
greater than 1.5 dB per 40 ms and less than 2.5 dB per 40 ms. 5
Test 10: 6
(a) The average rate of change in mean output power for 9600 bps data rate shall be 7
greater than 11.2 dB per 80 ms and less than 20.8 dB per 80 ms. 8
(b) Following the reception of any valid power control bit bit that occurs 2.5 ms after the 9
100 consecutive '0' valid power control bits, the mean output power of the mobile 10
station shall be within 0.15 dB of its final value in less than 500 µs. 11
Test 11: 12
(a) The average rate of change in mean output power for 4800 bps data rate shall be 13
greater than 5.6 dB per 80 ms and less than 10.4 dB per 80 ms. 14
Test 12: 15
(a) The average rate of change in mean output power for 2400 bps data rate shall be 16
greater than 2.8 dB per 80 ms and less than 5.2 dB per 80 ms. 17
Test 13: 18
(a) The average rate of change in mean output power for 1200 bps data rate shall be 19
greater than 1.4 dB per 80 ms and less than 2.6 dB per 80 ms. 20
4.4.5 Maximum RF Output Power 21
4.4.5.1 Definition 22
For each Reverse Traffic Channel Radio Configuration that the mobile station supports, the 23
maximum RF output power is defined as the maximum power that the mobile station 24
transmits as measured at the mobile station antenna connector. 25
4.4.5.2 Method of Measurement 26
1. Configure all of the open loop parameters to their maximum settings. 27
If the Access Channel is used, set the following parameters of the Access 28
Parameters Message as specified below: 29
30
3GPP2 C.S0011-A Ballot Resolution Version
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Parameter Value (Decimal)
NOM_PWR 7 (7 dB)
INIT_PWR 15 (15 dB)
PWR_STEP 7 (7 dB/step)
NUM_STEP 15 (16 probes/sequence)
MAX_RSP_SEQ 15 (15 sequences)
1
If the Enhanced Access Channel is used, set the following parameters of the 2
Enhanced Access Parameters Message as specified below: 3
4
Parameter Value (Decimal)
NOM_PWR_EACH 15 (15 dB)
INIT_PWR_EACH 15 (15 dB)
PWR_STEP_EACH 7 (7 dB/step)
NUM_STEP_EACH 15 (16 probes/sequence)
EACH_MAX_RSP_SEQ 15 (15 sequences)
5
2. Connect the base station to the mobile station antenna connector as shown in 6
Figure 6.5.1-4. The AWGN generator and the interference generator are not 7
applicable in this test. 8
3. For each band class that the mobile station supports, configure the mobile station 9
to operate in that band class and perform steps 4 through 20. 10
4. If the mobile station supports Reverse Traffic Channel Radio Configuration 1 and 11
Forward Traffic Channel Radio Configuration 1, set up a call using Fundamental 12
Channel Test Mode 1 (see 1.3) with 9600 bps data rate only and perform steps 10 13
through 12. 14
5. If the mobile station supports the Radio Configuration 3 Reverse Fundamental 15
Channel and demodulation of Radio Configuration 3, 4, or 5, set up a call using 16
Fundamental Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and 17
perform steps 10 through 12. 18
6. If the mobile station supports the Radio Configuration 3 Reverse Dedicated Control 19
Channel and demodulation of Radio Configuration 3, 4, or 5, set up a call using 20
Dedicated Control Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and 21
100% frame activity and perform steps 10 through 12. 22
7. If the mobile station supports the Radio Configuration 3 Reverse Fundamental 23
Channel, Radio Configuration 3 Reverse Dedicated Control Channel and 24
demodulation of Radio Configuration 3, 4, or 5, set up a call using Fundamental 25
3GPP2 C.S0011-A Ballot Resolution Version
4-33
Channel Test Mode 3 (see 1.3) with 1500 bps Fundamental Channel data rate only 1
and 9600 bps Dedicated Control Channel with 100 % frame activity, and perform 2
steps 10 through 12. 3
8. If the mobile station supports the Radio Configuration 3 Reverse Fundamental 4
Channel, Radio Configuration 3 Reverse Supplemental Channel 0 and 5
demodulation of Radio Configuration 3, 4, or 5, set up a call using Supplemental 6
Channel Test Mode 3 (see 1.3) with 9600 bps Fundamental Channel and 9600 bps 7
Supplemental Channel 0 data rate, and perform steps 10 through 12. 8
9. If the mobile station supports the Radio Configuration 3 Reverse Dedicated Control 9
Channel, Radio Configuration 3 Reverse Supplemental Channel 0 and 10
demodulation of Radio Configuration 3, 4, or 5, set up a call using Supplemental 11
Channel Test Mode 3 (see 1.3) with 9600 bps Dedicated Control Channel with 100% 12
frame activity and 9600 bps Supplemental Channel 0 data rate, and perform steps 13
10 through 12. 14
10. Set the test parameters as specified in Table 4.4.5.2-1. 15
11. Send continuously 0 power control bits to the mobile station. 16
12. Measure the mobile station output power at the mobile station antenna connector. 17
13. If the mobile station supports the Radio Configuration 5 Reverse Fundamental 18
Channel and demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using 19
Fundamental Channel Test Mode 7 (see 1.3) with 9600 bps data rate only and 20
perform steps 18 through 20. 21
14. If the mobile station supports the Radio Configuration 5 Reverse Dedicated Control 22
Channel and demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using 23
Dedicated Control Channel Test Mode 7 (see 1.3) with 9600 bps data rate only and 24
100% frame activity and perform steps 18 through 20. 25
15. If the mobile station supports the Radio Configuration 5 Reverse Fundamental 26
Channel, Radio Configuration 5 Reverse Dedicated Control Channel and 27
demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using Fundamental 28
Channel Test Mode 7 (see 1.3) with 1500 bps Fundamental Channel data rate only 29
and 9600 bps Dedicated Control Channel with 100 % frame activity, and perform 30
steps 18 through 20. 31
16. If the mobile station supports the Radio Configuration 5 Reverse Fundamental 32
Channel, Radio Configuration 5 Reverse Supplemental Channel 0 and 33
demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using Supplemental 34
Channel Test Mode 7 (see 1.3) with 9600 bps Fundamental Channel and 9600 bps 35
Supplemental Channel 0 data rate, and perform steps 18 through 20. 36
17. If the mobile station supports the Radio Configuration 5 Reverse Dedicated Control 37
Channel, Radio Configuration 5 Reverse Supplemental Channel 0 and 38
demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using Supplemental 39
Channel Test Mode 7 (see 1.3) with 9600 bps Dedicated Control Channel with 100% 40
frame activity and 9600 bps Supplemental Channel 0 data rate, and perform steps 41
18 through 20. 42
3GPP2 C.S0011-A Ballot Resolution Version
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18. Set the test parameters as specified in Table 4.4.5.2-2. 1
19. Send continuously 0 power control bits to the mobile station. 2
20. Measure the mobile station output power at the mobile station antenna connector. 3
4
Table 4.4.5.2-1. Test Parameters for Maximum RF Output Power for Spreading Rate 1 5
Parameter Units Value
Îor dBm/1.23 MHz -104
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4
6
Table 4.4.5.2-2. Test Parameters for Maximum RF Output Power for Spreading Rate 3 7
Parameter Units Value
Îor dBm/3.69 MHz -99
orc
IEPilot
dB -10
orc
IE Traffic
dB -12.4
8
4.4.5.3 Minimum Standard 9
For each radio configuration that the mobile station supports, the maximum output power 10
of each mobile station class shall be such that the maximum radiated power for the mobile 11
station class using the antenna gain recommended by the mobile station manufacturer is 12
within the limits specified in Table 4.4.5.3-1. When the mobile station is transmitting only 13
on the Reverse Dedicated Control Channel, the maximum output power requirements of the 14
mobile station specified in Table 4.4.5.3-1 may be reduced by 2.5 dB. When the mobile 15
station is transmitting only with the combination of Reverse Dedicated Control Channel and 16
1500 bps Reverse Fundamental Channel, the maximum output power requirements of the 17
mobile station specified in Table 4.4.5.3-1 may be reduced by 2 dB. 18
19
3GPP2 C.S0011-A Ballot Resolution Version
4-35
Table 4.4.5.3-1. Effective Radiated Power at Maximum Output Power 1
Band Class Mobile Station Class
Radiating Measurement
Lower Limit Upper Limit
Class I ERP 1 dBW (1.25 W) 8 dBW (6.3 W)
0, 3, and 9 Class II ERP -3 dBW (0.5 W) 4 dBW (2.5 W)
Class III ERP -7 dBW (0.2 W) 0 dBW (1.0 W)
Class I EIRP -2 dBW (0.63 W) 3 dBW (2.0 W)
Class II EIRP -7 dBW (0.2 W) 0 dBW (1.0 W)
Class III EIRP -12 dBW (63 mW) -3 dBW (0.5 W)
Class IV EIRP -17 dBW (20 mW) -6 dBW (0.25 W)
1, 4 and 8
Class V EIRP -22 dBW (6.3 mW) -9 dBW (0.13 W)
Class I EIRP -2 dBW (0.63 W) 3 dBW (2.0 W)
Class II EIRP -7 dBW (0.2 W) 0 dBW (1.0 W)
Class III EIRP -12 dBW (63 mW) -3 dBW (0.5 W)
Class IV EIRP -17 dBW (20 mW) -6 dBW (0.25 W)
6 (outside Japan)
Class V EIRP -22 dBW (6.3 mW) -9 dBW (0.13 W)
Class I and II EIRP -10 dBW (0.1 W) -6 dBW (0.25 W)
Class III EIRP -12 dBW (63 mW) -6 dBW (0.25 W)
Class IV EIRP -17 dBW (20 mW) -6 dBW (0.25 W)
6 (in Japan)
Class V EIRP -22 dBW (6.3 mW) -9 dBW (0.13 W)
Class II ERP 1 dBW (1.25 W) 8 dBW (6.3 W)
2 Class III ERP -3 dBW (0.5 W) 4 dBW (2.5 W)
Class IV ERP -7 dBW (0.2 W) 0 dBW (1.0 W)
Class I ERP 3 dBW (2.0 W) 10 dBW (10 W)
Class II ERP -2 dBW (0.63 W) 5 dBW (3.2 W)
Class III ERP -7 dBW (0.2 W) 0 dBW (1.0 W)
5
Class IV ERP -12 dBW (63 mW) -5 dBW (320 mW)
7 Class I ERP -3 dBW (0.5 W) 4 dBW (2.5 W)
Class II ERP -7 dBW (0.2 W) 0 dBW (1.0 W)
For Band Class 6 operation, the mobile station should use country code information in the overhead messages to determine the correct maximum radiated power allowed.
2
3GPP2 C.S0011-A Ballot Resolution Version
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4.4.6 Minimum Controlled Output Power 1
4.4.6.1 Definition 2
The minimum controlled output power of the mobile station is the output power, measured 3
at the mobile station antenna connector, when both closed loop and open loop power 4
control indicate minimum output. 5
4.4.6.2 Method of Measurement 6
1. Connect the base station to the mobile station antenna connector as shown in 7
Figure 6.5.1-4. The AWGN generator and the interference generator are not 8
applicable in this test. 9
2. For each band class that the mobile station supports, configure the base station 10
and mobile station to operate in that band class and perform steps 3 through 7. 11
3. If the mobile station supports demodulation of Radio Configuration 1, 2, 3, 4, or 5, 12
set up a call using Fundamental Channel Test Mode 1 or 3 or Dedicated Control 13
Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 5 14
through 7. 15
4. If the mobile station supports demodulation of Radio Configuration 6, 7, 8, or 9, set 16
up a call using Fundamental Channel Test Mode 7 or Control Channel Test Mode 7 17
(see 1.3) with 9600 bps data rate only and perform steps 5 through 7. 18
5. Set the test parameters as specified in Table 4.4.6.2-1. 19
6. Send continuously 1 power control bits to the mobile station. 20
7. Measure the mobile station output power at the mobile station antenna connector. 21
22
Table 4.4.6.2-1. Test Parameters for Minimum Controlled Output Power 23
Parameter Units Value
Îor dBm/1.23 MHz -25
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4
24
4.4.6.3 Minimum Standard 25
With both closed loop and open loop power control set to minimum, the mean output power 26
of the mobile station shall be less than -50 dBm/1.23 MHz for Spreading Rate 1 or -50 27
dBm/3.69 MHz for Spreading Rate 3 centered at the CDMA Channel frequency. 28
3GPP2 C.S0011-A Ballot Resolution Version
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4.4.7 Standby Output Power and Gated Output Power 1
4.4.7.1 Definition 2
The standby output power is the mobile station output power when its transmit functions 3
are disabled (e.g., during the Mobile Station Initialization State, Mobile Station Idle State and 4
during the System Access State when the mobile station does not transmit access probes). 5
When operating in the variable data rate transmission mode in Radio Configurations 1 and 6
2, or when operating with the Reverse Pilot Channel gating or Reverse Fundamental 7
Channel gating enabled, the mobile station transmits at nominal controlled power level only 8
during gated-on periods, each defined as a power control group. The transmitted power 9
level is suppressed during gated-off periods. This test measures the time response of the 10
mean output power for a gated-on power control group (1.25 ms). 11
4.4.7.2 Method of Measurement 12
1. Connect the base station to the mobile station antenna connector as shown in 13
Figure 6.5.1-4. The AWGN generator and the interference generator are not 14
applicable in this test. 15
2. Set the test parameters as specified in Table 4.4.7.2-1. 16
3. Measure the output power, at the mobile station antenna connector, during the 17
Mobile Station Initialization State or during the Mobile Station Idle State. 18
4. Send a page to the mobile station and measure the output power, at the mobile 19
station antenna connector, during the time periods between transmission of access 20
probes. 21
5. If the mobile station supports Radio Configuration 1 or 2, set up a call using 22
Fundamental Channel Test Mode 1 (see 1.3) with 1200 bps data rate only and 23
perform steps 10 through 14. 24
6. If the mobile station supports Reverse Radio Configuration 3 or 4, and if the mobile 25
station supports Reverse Pilot Channel gating, set up a call using Dedicated Control 26
Channel Test Mode 3 (see 1.3). Send Non-Negotiable Service Configuration 27
information record messages to the mobile station, so that 28
PILOT_GATING_USE_RATE = 1 and PILOT_GATING_RATE = 01 (1/2 rate) or 10 29
(1/4 rate). The base station shall not transmit on the Forward Dedicated Control 30
Channel to the mobile station under test during the test. Perform steps 10 through 31
14. 32
7. If the mobile station supports Reverse Radio Configuration 5 or 6, and if the mobile 33
station supports Reverse Pilot Channel gating, set up a call using Dedicated Control 34
Channel Test Mode 7 (see 1.3). Send Non-Negotiable Service Configuration 35
information record messages to the mobile station, so that 36
PILOT_GATING_USE_RATE = 1 and PILOT_GATING_RATE = 01 (1/2 rate) or 10 37
(1/4 rate). The base station shall not transmit on the Forward Dedicated Control 38
Channel to the mobile station under test during the test. Perform steps 10 through 39
14. 40
3GPP2 C.S0011-A Ballot Resolution Version
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8. If the mobile station supports Reverse Radio Configuration 3 or 4, and if the mobile 1
station supports Reverse Fundamental Channel gating, set up a call using 2
Fundamental Channel Test Mode 3 (see 1.3). Send an Extended Channel 3
Assignment Message with REV_FCH_GATING_MODE equal to 1 (50% Reverse 4
Fundamental Channel transmission duty cycle). Send continuous 20 ms frames at 5
1500 bps data rate to the mobile station. Perform steps 10 through 14. 6
9. If the mobile station supports Reverse Radio Configuration 5 or 6, and if the mobile 7
station supports Reverse Fundamental Channel gating, set up a call using 8
Fundamental Channel Test Mode 7 (see 1.3). Send an Extended Channel 9
Assignment Message with REV_FCH_GATING_MODE equal to 1 (50% Reverse 10
Fundamental Channel transmission duty cycle). Send continuous 20 ms frames at 11
1500 bps data rate to the mobile station. Perform steps 10 through 14. 12
10. Send alternating 0 and 1 valid power control bits on the Forward Traffic Channel 13
or the Forward Power Control Subchannel. 14
11. Measure the time response of the mobile station output power, averaged over at 15
least 100 transitions to and 100 transitions from gated-on power control groups. 16
The power is measured at the mobile station antenna connector. 17
12. If gating is enabled, perform steps 13 and 14. 18
13. Send alternating 0 and 1 valid power control bits on the Forward Power Control 19
Subchannel. 20
14. Measure the ratio of the Reverse Fundamental Channel and the Reverse Pilot 21
Channel, averaged over at least 100 gated-on power control groups. The power is 22
measured at the mobile station antenna connector. 23
24
Table 4.4.7.2-1. Test Parameters for Standby Output Power and Gated Output Power 25
Parameter Units Value
Îor dBm/1.23 MHz -75
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4
26
4.4.7.3 Minimum Standard 27
Standby Output Power: 28
When the transmitter is disabled, the output noise power spectral density of the mobile 29
station shall be less than -61 dBm, measured in a 1 MHz resolution bandwidth at the 30
mobile station antenna connector, for frequencies within the mobile station transmit band. 31
Gated Output Power: 32
3GPP2 C.S0011-A Ballot Resolution Version
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Given an ensemble of power control groups, all with the same mean output power, the time 1
response of the ensemble average shall be within the limits shown in Figure 4.4.7.3-1. The 2
mean output power of the ensemble average is the mean value of gated-on output power 3
measured within a 1.25 ms time window. The measured width of response between points 3 4
dB below the mean output power shall be at least 1.25 × K − 0.003 ms and within the range 5
shown in Figure 4.4.7.3-1, where K is 1 for Radio Configurations 1, 2, or Reverse Pilot 6
Channel gating and 2 for Reverse Fundamental Channel gating. The output power level 7
outside of a 1.25 × K + 0.014 ms time window shall be at least 20 dB below the mean 8
output power of the ensemble average as shown in Figure 4.4.7.3-1. 9
The ratio of the Reverse Fundamental Channel and the Reverse Pilot Channel shall be 10
within 0.25 dB of 1.25 dB. 11
12
(1.25 × K - 0.003) ms
20 dB or tonoise floor
Time response of theensemble average
(average power control group)
Mean output power ofthe ensemble average
(reference line)
µs 7 µs 7
3 dB
13
Figure 4.4.7.3-1. Transmission Envelope Mask (Average Gated-on Power Control 14
Group) 15
16
4.4.8 Power Up Function Output Power 17
The tests in this section shall be performed if the mobile station supports the power up 18
function using Radio Configuration 1 or 2. 19
4.4.8.1 Definition 20
This test verifies the following power up function parameters: probe duration, initial power 21
offset, power increment between consecutive probes, time interval between consecutive 22
probes, the total number of PUF probes in one PUF attempt, and the maximum number of 23
full power PUF probes. 24
3GPP2 C.S0011-A Ballot Resolution Version
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4.4.8.2 Method of Measurement 1
1. Connect the base station to the mobile station antenna connector as shown in 2
Figure 6.5.1-4. The AWGN generator and the interference generator are not 3
applicable in this test. 4
2. Set up a call using Fundamental Channel Test Mode 1 (see 1.3). 5
3. Send alternating 0 and 1 power control bits on the Forward Power Control 6
Subchannel. 7
4. Set the base station to ignore all PUF attempts. 8
5. Send a Power Up Function Message to the mobile station with the values specified 9
below: 10
11
Parameter Value (Decimal)
PUF_SETUP_SIZE 0 (1 power control group)
PUF_PULSE_SIZE 15 (16 power control groups)
PUF_INTERVAL 2 (2 frames between start of subsequent PUF probes)
PUF_INIT_PWR 8 (8 dB)
PUF_PWR_STEP 1 (1 dB/step)
TOTAL_PUF_PROBES 3 (4 probes)
MAX_PWR_PUF 0 (1 pulse at max power)
PUF_FREQ_INCL 0 (same as current)
12
6. Measure the mobile station output power for each PUF probe at the antenna 13
connector. 14
7. Send a Power Up Function Message with the values specified below. Repeat step 6. 15
16
3GPP2 C.S0011-A Ballot Resolution Version
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Parameter Value (Decimal)
PUF_SETUP_SIZE 0 (1 power control group)
PUF_PULSE_SIZE 15 (16 power control groups)
PUF_INTERVAL 2 (2 frames between start of subsequent PUF probes)
PUF_INIT_PWR 16 (16 dB)
PUF_PWR_STEP 4 (4 dB/step)
TOTAL_PUF_PROBES 7 (8 probes)
MAX_PWR_PUF 2 (3 pulses at max power)
PUF_FREQ_INCL 0 (same as current)
1
4.4.8.3 Minimum Standard 2
In the first PUF probe attempt: 3
(a) The power increment between consecutive access probes in each PUF probe 4
attempt shall be 1 ± 0.33 dB. 5
(b) The duration of each PUF probe shall be between 20 ms and 22.5 ms, including the 6
setup time. 7
(c) There shall be two frames between the start of subsequent PUF probes. 8
(d) The number of PUF probes in the PUF probe attempt shall be four. 9
In the second PUF probe attempt: 10
(a) The power of the first PUF probe of each PUF probe attempt shall be 8 ± 2.67 dB 11
above the power of the PUF probes in the first PUF probe attempt. 12
(b) The power increment between consecutive PUF probes in each PUF probe attempt 13
shall be 4 ± 1.33 dB. 14
(c) The duration of each PUF probe shall be between 20 ms and 22.5 ms, including the 15
setup time. 16
(d) There shall be two frames between the start of subsequent PUF probes. 17
(e) The number of PUF probes in each PUF probe attempt shall be less than eight. 18
(f) The mobile station shall not transmit more than three PUF probes at full power. 19
4.4.9 Code Channel to Reverse Pilot Channel Output Power Accuracy 20
4.4.9.1 Definition 21
Code channel to Reverse Pilot Channel output power accuracy is the permissible error in 22
mobile station mean output power between each of the radiated code channels and the 23
Reverse Pilot Channel during steady state operation. 24
3GPP2 C.S0011-A Ballot Resolution Version
4-42
The tests shall be performed for mobile stations that support the Reverse Pilot Channel. 1
These tests shall be performed for each band class supported by the mobile station. 2
4.4.9.2 Method of Measurement 3
4.4.9.2.1 Code Channel Output Power for the Enhanced Access Channel Header, 4
Enhanced Access Channel Data, and Reverse Common Control Channel Data 5
1. Connect the base station to the mobile station antenna connector as shown in 6
Figure 6.5.1-4. The AWGN generator and the interference generator are not 7
applicable in this test. 8
2. For each band class that the mobile station supports, configure the base station 9
and mobile station to operate in that band class and perform steps 3 through 14. 10
3. Set the Reverse Link Attribute Adjustment Gain Table and Reverse Channel 11
Adjustment Gain Table maintained by the mobile station to 0. 12
4. Set the test parameters as specified below: 13
14
Parameter Units Value
Îor dBm/1.23 MHz -75
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4 (SR 1)
-12.4 (SR 3)
15
5. Configure the base station so that the mobile station uses the Spreading Rate 1 or 16
Spreading Rate 3 Enhanced Access Channel. 17
6. Set the parameter values in the Enhanced Access Parameters Message to the values 18
specified below. 19
20
Parameter Value (Decimal)
REACH_RATE_MODE 0 (9600 bps, 20 ms frame size)
REACH_MODE 0 (Basic Access Mode - no CACH or CPCCH)
EACH_PREAMBLE_NUM_FRAC 0 (no preamble)
EACH _PREAMBLE_ADD_DURATION 0 (no additional preamble)
EACH_MAX_RSP_SEQ 1 (1 sequence)
21
7. Send a page to the mobile station. 22
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8. Monitor the mobile station transmitter output at the antenna connector with a 1
Code Domain Power Analyzer described in 6.4.2.2 during transmission of a probe 2
and measure the relative mean output power of the Enhanced Access Channel Data 3
to the Reverse Pilot Channel. 4
9. Configure the base station so that the mobile station monitors the Forward 5
Common Control Channel for Spreading Rate 1 (or Spreading Rate 3) and the 6
Common Assignment Channel. 7
10. Set the following values in the Enhanced Access Parameters Message: 8
9
Parameter Value (Decimal)
RCCCH_RATE_MODE 0 (9600 bps, 20 ms frame size)
ACCESS_MODE 2 (Reservation Access Mode)
APPLICABLE_MODES 1 (Parameters are for Reservation Access Mode)
RA_PC_DELAY 4 (MS to ignore 4 PC bits after start of R-CCCH transmission)
RA_CPCCH_STEP_UP 1 (up step size is 0.5 dB)
RA_CPCCH_STEP_DN 1 (down step size is 0.5 dB)
CPCCH_RATE 2 (800 Hz power control rate)
NUM_PCSCH_RA 24 (24 Power Control Subchannels)
10
11. Send a Status Request Order on the Forward Common Control Channel. 11
12. Once the end of the header on the Enhanced Access Channel is detected at the 12
base station, send an Early Acknowledgement Channel Assignment Message on the 13
Common Assignment Channel addressed to the mobile station. 14
13. Send alternating 0 and 1 power control bits on the Common Power Control 15
Subchannel assigned to the mobile station. 16
14. Monitor the mobile station transmitter output at the antenna connector with a 17
Code Domain Power Analyzer described in 6.4.2.2 and measure the relative mean 18
output power of the Enhanced Access Channel Header and Reverse Common 19
Control Channel to the Reverse Pilot Channel. 20
4.4.9.2.2 Code Channel Output Power for the Reverse Traffic Channel 21
1. Connect the base station to the mobile station antenna connector as shown in 22
Figure 6.5.1-4. The AWGN generator and the interference generator are not 23
applicable in this test. 24
2. For each band class that the mobile station supports, configure the base station 25
and mobile station to operate in that band class and perform steps 3 through 12. 26
3GPP2 C.S0011-A Ballot Resolution Version
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3. Set the Reverse Link Attribute Adjustment Gain Table and Reverse Channel 1
Adjustment Gain Table maintained by the mobile station to 0. 2
4. If the mobile station supports operation on the Reverse Fundamental Channel, set 3
up a call using Fundamental Channel Test Mode 3 (or 7) (see 1.3) with 9600 bps 4
data rate only, 20 ms frame length Radio Configuration 3 (or 7) Reverse 5
Fundamental Channel and perform steps 13 through 15. 6
5. If the mobile station supports operation on the Reverse Fundamental Channel, set 7
up a call using Fundamental Channel Test Mode 3 (or 7) (see 1.3) with 4800 bps 8
data rate only, 20 ms frame length Radio Configuration 3 (or 7) Reverse 9
Fundamental Channel and perform steps 13 through 15. 10
6. If the mobile station supports operation on the Reverse Fundamental Channel, set 11
up a call using Fundamental Channel Test Mode 3 (or 7) (see 1.3) with 2700 bps 12
data rate only, 20 ms frame length Radio Configuration 3 (or 7) Reverse 13
Fundamental Channel and perform steps 13 through 15. 14
7. If the mobile station supports operation on the Reverse Fundamental Channel, set 15
up a call using Fundamental Channel Test Mode 3 (or 7) (see 1.3) with 1500 bps 16
data rate only, 20 ms frame length Radio Configuration 3 (or 7) Reverse 17
Fundamental Channel and perform steps 13 through 15. 18
8. If the mobile station supports operation on the Reverse Dedicated Control Channel, 19
set up a call using Dedicated Control Channel Test Mode 3 (or 7) (see 1.3) with 20
9600 bps data rate only, 20 ms frame length Radio Configuration 3 (or 7) Reverse 21
Dedicated Control Channel and perform steps 13 through 15. 22
9. If the mobile station supports convolutional coding on the Reverse Supplemental 23
Channel, set up a call using Supplemental Channel Test Mode 3 (or 7) (see 1.3) 24
with 9600 bps data rate only, 20 ms frame length with convolutional coding of the 25
Radio Configuration 3 (or 7) Reverse Supplemental Channel and perform steps 13 26
through 15. 27
10. If the mobile station supports convolutional coding on the Reverse Supplemental 28
Channel, set up a call using Supplemental Channel Test Mode 3 (or 7) (see 1.3) 29
with both the highest data rate supported by the mobile station using a 20 ms 30
frame length with convolutional coding of the Radio Configuration 3 (or 7) Reverse 31
Supplemental Channel, and either a Radio Configuration 3 (or 7) 9600 bps, 20 ms 32
frame length Reverse Fundamental Channel or 9600 bps, 20 ms frame length 33
Reverse Dedicated Control Channel with 100% duty cycle and perform steps 13 34
through 15. 35
11. If the mobile station supports turbo coding on the Reverse Supplemental Channel, 36
set up a call using Supplemental Channel Test Mode 3 (or 7) (see 1.3) with 19200 37
bps data rate only, 20 ms frame length with turbo coding of the Radio 38
12. If the mobile station supports operation on the Reverse Supplemental Channel 41
using turbo coding, set up a call using Supplemental Channel Test Mode 3 (or 7) 42
3GPP2 C.S0011-A Ballot Resolution Version
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(see 1.3) with both the highest data rate supported by the mobile station using a 20 1
ms frame length with turbo coding of the Radio Configuration 3 (or 7) Reverse 2
Supplemental Channel, and either a Radio Configuration 3 (or 7) 9600 bps, 20 ms 3
frame length Reverse Fundamental Channel or 9600 bps, 20 ms frame length 4
Reverse Dedicated Control Channel with 100% duty cycle and perform steps 13 5
through 15. 6
13. Set the test parameters as specified below: 7
8
Parameter Units Value
Îor dBm/1.23 MHz -75
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4 (SR 1)
-12.4 (SR 3)
9
14. Send alternating 0 and 1 power control bits on the Forward Traffic Channel. 10
15. Monitor the mobile station transmitter output at the antenna connector with a 11
Code Domain Power Analyzer described in 6.4.2.2 and measure the relative mean 12
output power of each active code channel to the Reverse Pilot Channel. 13
4.4.9.3 Minimum Standard 14
The mean output power difference between the Enhanced Access Channel Header and 15
Reverse Pilot Channel shall be 6.75 ± 0.25 dB. 16
The mean output power difference between either the Enhanced Access Channel Data or 17
Reverse Common Control Channel and the Reverse Pilot Channel shall be 3.75 ± 0.25 dB. 18
For tests not involving the Reverse Supplemental Channel, the mean output power 19
difference between each Reverse Traffic Channel code channel and the Reverse Pilot 20
Channel shall be the code channel accuracy specified in Table 4.4.9.3-1. 21
For tests involving the Reverse Supplemental Channel, the mean output power difference 22
between the Reverse Supplemental Channel code channel and the Reverse Pilot Channel 23
shall be the code accuracy specified in Table 4.4.9.3-1 and 4.4.9.3-2. For the Reverse 24
Fundamental Channel (or Reverse Dedicated Control Channel, whichever is the 25
configuration) being transmitted in addition to the Supplemental Channel, the mean output 26
power difference between the Reverse Fundamental Channel (or Reverse Dedicated Control 27
Channel) code channel and the Reverse Pilot Channel shall be the code accuracy specified 28
in Table 4.4.9.3-3 and 4.4.9.3-4. 29
30
3GPP2 C.S0011-A Ballot Resolution Version
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Table 4.4.9.3-1. Code Channel Accuracy Requirements for the Reverse Fundamental 1
Channel, Reverse Dedicated Control Channel and (Convolutional Coded) Reverse 2
Supplemental Channel 3
Data Rate (bps)
Code Channel Accuracy (dB)
1500 -5.88 ± 0.25
2700 -2.75 ± 0.25
4800 -0.25 ± 0.25
9600 3.75 ± 0.25
19200 6.25 ± 0.25
38400 7.5 ± 0.25
76800 9 ± 0.25
153600 10.5 ± 0.25
307200 12 ± 0.25
614400 14 ± 0.25
4
Table 4.4.9.3-2. Code Channel Accuracy Requirements for the (Turbo Coded) Reverse 5
Supplemental Channel 6
Data Rate (bps)
Code Channel Accuracy (dB)
19200 5.5 ± 0.25
38400 7 ± 0.25
76800 8.5 ± 0.25
153600 9.5 ± 0.25
307200 11 ± 0.25
614400 14 ± 0.25
1036800 15.63 ± 0.25
7
3GPP2 C.S0011-A Ballot Resolution Version
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Table 4.4.9.3-3. Code Channel Accuracy Requirements for the 9600 bps Reverse 1
Fundamental Channel (or 9600 bps Reverse Dedicated Control Channel) Being 2
Transmitted in Addition to the (Convolutional Coded) Reverse Supplemental Channel 3
R-SCH Data Rate (bps)
R-FCH (or R-DCCH) Code Channel Accuracy (dB)
9600 3.75 ± 0.25
19200 3.63 ± 0.25
38400 2.38 ± 0.25
76800 1.13 ± 0.25
153600 -0.75 ± 0.25
307200 -3 ± 0.35
614400 -4.75 ± 0.6
4
Table 4.4.9.3-4. Code Channel Accuracy Requirements for the 9600 bps Reverse 5
Fundamental Channel (or 9600 bps Reverse Dedicated Control Channel) Being 6
Transmitted in Addition to the (Turbo Coded) Reverse Supplemental Channel 7
R-SCH Data Rate (bps)
R-FCH (or R-DCCH) Code Channel Accuracy (dB)
19200 3.5 ± 0.25
38400 2.5 ± 0.25
76800 1.375 ± 0.25
153600 -0.375 ± 0.25
307200 -2.5 ± 0.25
614400 -3.5 ± 0.35
1036800 -6 ± 0.6
8
4.4.10 Reverse Pilot Channel Transmit Phase Discontinuity 9
4.4.10.1 Definition 10
This test measures the mobile station Reverse Pilot Channel phase over the total range of 11
mobile station output power levels. 12
The tests shall be performed for mobile stations that support the Reverse Pilot Channel. 13
These tests shall be performed for each spreading rate and band class supported by the 14
mobile station. 15
3GPP2 C.S0011-A Ballot Resolution Version
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4.4.10.2 Method of Measurement 1
1. Connect the base station to the mobile station antenna connector as shown in Figure 2
6.5.1-4. The AWGN generator and the interferencegenerator are not applicable in this 3
test. 4
2. Set the power control step size to 1 dB. 5
3. For each band class that the mobile station supports, configure the base station and 6
mobile station to operate in that band class and perform steps 4 through 13. 7
4. If the mobile station supports operation on the Reverse Fundamental Channel, set up a 8
call using Fundamental Channel Test Mode 3 (see 1.3) with 9600 bps data rate only 9
Radio Configuration 3 Reverse Fundamental Channel. Otherwise, set up a call using 10
Dedicated Control Channel Test Mode 3 (see 1.3) with 9600 bps data rate only Radio 11
Configuration 3 Reverse Dedicated Control Channel with 100% duty cycle. Perform 12
steps 6 through 13. 13
5. If the mobile station supports operation on the Reverse Fundamental Channel, set up a 14
call using Fundamental Channel Test Mode 7 (see 1.3) with 9600 bps data rate only 15
Radio Configuration 5 Reverse Fundamental Channel. Otherwise, set up a call using 16
Dedicated Control Channel Test Mode 7 (see 1.3) with 9600 bps data rate only Radio 17
Configuration 5 Reverse Dedicated Control Channel with 100% duty cycle. Perform 18
steps 6 through 13. 19
6. Set the attenuation in the Forward CDMA Channel to yield a Reverse CDMA Channel 20
output power level, measured at the mobile station antenna connector, of -50 dBm and 21
perform steps 11 through 13. 22
7. Set the attenuation in the Forward CDMA Channel to yield a Reverse CDMA Channel 23
output power level, measured at the mobile station antenna connector, of -35 dBm and 24
perform steps 11 through 13. 25
8. Set the attenuation in the Forward CDMA Channel to yield a Reverse CDMA Channel 26
output power level, measured at the mobile station antenna connector, of -20 dBm and 27
perform steps 11 through 13. 28
9. Set the attenuation in the Forward CDMA Channel to yield a Reverse CDMA Channel 29
output power level, measured at the mobile station antenna connector, of -5 dBm and 30
perform steps 11 through 13. 31
10. Set the attenuation in the Forward CDMA Channel to yield a Reverse CDMA Channel 32
output power level, measured at the mobile station antenna connector, of + 10 dBm and 33
perform steps 11 through 13. 34
11. Measure the Reverse Pilot Channel phase at the mobile station antenna connector while 35
transmitting an arbitrary number of alternating 0 and 1 valid power control bits (the 36
last bit is a 1 bit), followed by ten contiguous 00011000110001110101010101010101 37
3GPP2 C.S0011-A Ballot Resolution Version
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valid power control bit sequences6, and followed by ten contiguous 1
11100111001110000101010101010101 valid power control bit sequences. Ensure that 2
the mobile station output power level changes within the requirements of this document 3
for each closed loop power control command sent to the mobile station. 4
12. Measure the Reverse Pilot Channel phase at the mobile station antenna connector while 5
transmitting an arbitrary number of alternating 0 and 1 valid power control bits (the 6
last bit is a 1 bit), followed by ten contiguous 00000000011111110101010101010101 7
valid power control bit sequences, and followed by ten contiguous 8
11111111100000000101010101010101 valid power control bit sequences. Ensure that 9
the mobile station output power level changes within the requirements of this document 10
for each closed loop power control command sent to the mobile station. 11
13. Measure the Reverse Pilot Channel phase at the mobile station antenna connector while 12
transmitting an arbitrary number of alternating 0 and 1 valid power control bits (the 13
last bit is a 1 bit), followed by sixteen consecutive 0 valid power control bits, and 14
followed by sixteen consecutive 1 valid power control bits. Ensure that the mobile 15
station output power level changes within the requirements of this document for each 16
closed loop power control command sent to the mobile station. 17
4.4.10.3 Minimum Standard 18
For all tests, the mobile station shall meet the following requirements on transmitted 19
Reverse Pilot Channel phase: 20
a) not to exceed more than one type one phase discontinuity in any 5 ms period over the 21
full range of mobile station output power, and 22
b) not to exceed more than one type two phase discontinuity in any 20 ms period over the 23
full range of mobile station output power, 24
where a type one phase discontinuity is defined as a phase change of greater than 56 25
degrees in less than 0.5 ms, and a type two phase discontinuity is a phase change of 26
greater than 90 degrees in less than 1 ms. 27
4.4.11 Reverse Traffic Channel Output Power During Changes in Data Rate 28
4.4.11.1 Definition 29
This test verifies the time response of the Reverse Traffic Channel output power at data rate 30
transition boundaries. 31
This test shall be performed for mobile stations that support the Reverse Supplemental 32
Channel. This test shall be performed for each band class supported by the mobile station. 33
6 The last sixteen power control bits of each sequence, i.e. 0101010101010101, are included to assist with phase transient test equipment pilot tracking loop reacquisition.
3GPP2 C.S0011-A Ballot Resolution Version
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4.4.11.2 Method of Measurement 1
1. Connect the base station to the mobile station antenna connector as shown in 2
Figure 6.5.1-4. The AWGN generator and interference generator are not applicable 3
in this test. 4
2. For each band class that the mobile station supports, configure the base station 5
and mobile station to operate in that band class and perform steps 3 through 10. 6
3. Set the Reverse Link Attribute Adjustment Gain Table and Reverse Channel 7
Adjustment Gain Table maintained by the mobile station to 0. 8
4. If the mobile station supports the Radio Configuration 3 Reverse Supplemental 9
Channel, set up a call using either Fundamental Channel Test Mode 3 or Dedicated 10
Control Channel Test Mode 3 with 9600 bps data rate only (see 1.3) and perform 11
steps 6 through 8. 12
5. If the mobile station supports the Radio Configuration 5 Reverse Supplemental 13
Channel, set up a call using either Fundamental Channel Test Mode 7 or Dedicated 14
Control Channel Test Mode 7 with 9600 bps data rate only (see 1.3) and perform 15
steps 6 through 8. 16
6. Set the test parameters as specified below: 17
18
Parameter Units Value
Îor dBm/1.23 MHz -75
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4 (SR 1)
-12.4 (SR 3)
19
7. Configure the base station to direct the mobile station to periodically start and stop 20
transmission using the lowest supported data rate on the Reverse Supplemental 21
Channel and perform steps 9 and 10. 22
8. Configure the base station to direct the mobile station to periodically start and stop 23
transmission using the highest supported data rate on the Reverse Supplemental 24
Channel and perform steps 9 and 10. 25
9. Send alternating 0 and 1 power control bits on the Forward Traffic Channel. 26
10. Measure the mobile station output power at the data rate transition frame 27
boundary for at least 100 transitions in data rate. 28
4.4.11.3 Minimum Standard 29
The mean output power of the mobile station shall be within ±0.5 dB of its final value 30
within 200 µs of the data rate transition frame boundary. 31
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4.5 Limitations on Emissions 1
4.5.1 Conducted Spurious Emissions 2
4.5.1.1 Definition 3
Conducted spurious emissions are emissions at frequencies that are outside the assigned 4
CDMA Channel, measured at the mobile station antenna connector. This test measures the 5
spurious emissions during continuous transmission. 6
4.5.1.2 Method of Measurement 7
1. Connect the base station to the mobile station antenna connector as shown in 8
Figure 6.5.1-4. The AWGN generator and the interferencegenerator are not 9
applicable in this test. Connect a spectrum analyzer (or other suitable test 10
equipment) to the mobile station antenna connector. 11
2. For each band class and radio configuration that the mobile station supports, 12
configure the base station and mobile station to operate in that band class and 13
perform steps 3 through 17. 14
3. Set the following parameters of the Access Parameters Message as specified below: 15
16
Parameter Value (Decimal)
NOM_PWR 7 (7 dB)
INIT_PWR 15 (15 dB)
PWR_STEP 7 (7 dB/step)
NUM_STEP 15 (16 probes/sequence)
MAX_RSP_SEQ 15 (15 sequences)
17
If the Enhanced Access Channel is used, set the following parameters of the 18
Enhanced Access Parameters Message as specified below: 19
20
Parameter Value (Decimal)
NOM_PWR_EACH 15 (15 dB)
INIT_PWR_EACH 15 (15 dB)
PWR_STEP_EACH 7 (7 dB/step)
NUM_STEP_EACH 15 (16 probes/sequence)
EACH_MAX_RSP_SEQ 15 (15 sequences)
21
4. If the mobile station supports Reverse Traffic Channel Radio Configuration 1 and 22
Forward Traffic Channel Radio Configuration 1, set up a call using Fundamental 23
3GPP2 C.S0011-A Ballot Resolution Version
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Channel Test Mode 1 (see 1.3) with 9600 bps data rate only and perform steps 15 1
through 17. 2
5. If the mobile station supports the Radio Configuration 3 Reverse Fundamental 3
Channel and demodulation of Radio Configuration 3, 4, or 5, set up a call using 4
Fundamental Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and 5
perform steps 15 through 17. 6
6. If the mobile station supports the Radio Configuration 3 Reverse Dedicated Control 7
Channel and demodulation of Radio Configuration 3, 4, or 5, set up a call using 8
Dedicated Control Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and 9
100% frame activity and perform steps 15 through 17. 10
7. If the mobile station supports the Radio Configuration 3 Reverse Fundamental 11
Channel, Radio Configuration 3 Reverse Dedicated Control Channel and 12
demodulation of Radio Configuration 3, 4, or 5, set up a call using Fundamental 13
Channel Test Mode 3 (see 1.3) with 1500 bps Fundamental Channel data rate only 14
and 9600 bps Dedicated Control Channel with 100 % frame activity, and perform 15
steps 15 through 17. 16
8. If the mobile station supports the Radio Configuration 3 Reverse Fundamental 17
Channel, Radio Configuration 3 Reverse Supplemental Channel 0 and 18
demodulation of Radio Configuration 3, 4, or 5, set up a call using Supplemental 19
Channel Test Mode 3 (see 1.3) with 9600 bps Fundamental Channel and 9600 bps 20
Supplemental Channel 0 data rate, and perform steps 15 through 17. 21
9. If the mobile station supports the Radio Configuration 3 Reverse Dedicated Control 22
Channel, Radio Configuration 3 Reverse Supplemental Channel 0 and 23
demodulation of Radio Configuration 3, 4, or 5, set up a call using Supplemental 24
Channel Test Mode 3 (see 1.3) with 9600 bps Dedicated Control Channel with 100% 25
frame activity and 9600 bps Supplemental Channel 0 data rate, and perform steps 26
15 through 17. 27
10. If the mobile station supports the Radio Configuration 5 Reverse Fundamental 28
Channel and demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using 29
Fundamental Channel Test Mode 7 (see 1.3) with 9600 bps data rate only and 30
perform steps 15 through 17. 31
11. If the mobile station supports the Radio Configuration 5 Reverse Dedicated Control 32
Channel and demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using 33
Dedicated Control Channel Test Mode 7 (see 1.3) with 9600 bps data rate only and 34
100% frame activity and perform steps 15 through 17. 35
12. If the mobile station supports the Radio Configuration 5 Reverse Fundamental 36
Channel, Radio Configuration 5 Reverse Dedicated Control Channel and 37
demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using Fundamental 38
Channel Test Mode 7 (see 1.3) with 1500 bps Fundamental Channel data rate only 39
and 9600 bps Dedicated Control Channel with 100 % frame activity, and perform 40
steps 15 through 17. 41
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13. If the mobile station supports the Radio Configuration 5 Reverse Fundamental 1
Channel, Radio Configuration 5 Reverse Supplemental Channel 0 and 2
demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using Supplemental 3
Channel Test Mode 7 (see 1.3) with 9600 bps Fundamental Channel and 9600 bps 4
Supplemental Channel 0 data rate, and perform steps 15 through 17. 5
14. If the mobile station supports the Radio Configuration 5 Reverse Dedicated Control 6
Channel, Radio Configuration 5 Reverse Supplemental Channel 0 and 7
demodulation of Radio Configuration 6, 7, 8, or 9, set up a call using Supplemental 8
Channel Test Mode 7 (see 1.3) with 9600 bps Dedicated Control Channel with 100% 9
frame activity and 9600 bps Supplemental Channel 0 data rate, and perform steps 10
15 through 17. 11
15. Set the test parameters as specified in Table 4.5.1.2-1. 12
16. Send continuously 0 power control bits to the mobile station. 13
17. Measure the spurious emission levels. 14
15
Table 4.5.1.2-1. Test Parameters for Testing Spurious Emissions at Maximum RF 16
Output Power 17
Parameter Units Value
Îor dBm/1.23 MHz -104
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4
18
4.5.1.3 Minimum Standard 19
Depending on local radio regulations, the mobile station shall meet ITU Category A or B 20
emissions rules as appropriate. For Band Class 5, 6, 8, and 9, a mobile station shall meet 21
ITU Category B emission rules. 22
4.5.1.3.1 Spreading Rate 1 23
When transmitting in Band Class 0, 2, 3, 5, 7 or 9 with Spreading Rate 1, the spurious 24
emissions shall be less than all limits specified in Table 4.5.1.3.1-1. 25
26
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Table 4.5.1.3.1-1. Band Class 0, 2, 3, 5, 7 and 9 Transmitter Spurious Emission Limits 1
for Spreading Rate 1 2
For |∆∆∆∆f| Within the Range Emission Limit
885 kHz to 1.98 MHz Less stringent of -42 dBc/30 kHz or -54 dBm/1.23 MHz
1.98 MHz to 4.00 MHz Less stringent of -54 dBc/30 kHz or -54 dBm/1.23 MHz
9 kHz < f < 150 kHz 150 kHz < f < 30 MHz 30 MHz < f < 1 GHz 1 GHz < f < 12.75 GHz
Note: All frequencies in the measurement bandwidth shall satisfy the 2
restrictions on |∆f| where ∆f = center frequency - closer measurement edge 3
frequency (f). The requirements at offsets of 3.08 and 8.08 MHz are equivalent 4
to ACLR requirements of 33 and 43 dB from a Spreading Rate 3 mobile station 5
transmitter into a Spreading Rate 3 or IMT-DS mobile station receiver offset by 6
5 and 10 MHz respectively. 7
8
A Band Class 6 mobile station with Spreading Rate 3 shall also meet the requirements in 9
Table 4.5.1.3.2-2. 10
11
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Table 4.5.1.3.2-2. Additional Band Class 6 Transmitter Spurious Emission Limits 1
for Spreading Rate 3 2
Measurement Frequency
Emission Limit Victim Band
1893.5 to 1919.6 MHz -41 dBm / 300 kHz PHS
925 to 935 MHz -67 dBm / 100 kHz GSM 900
935 to 960 MHz -79 dBm / 100 kHz GSM 900
1805 to 1880 MHz -71 dBm / 100 kHz DCS 1800
Note: Measurements apply only when the measurement frequency is 3
at least 12.5 MHz from the CDMA center frequency. The non-PHS 4
band measurements are made on frequencies which are integer 5
multiples of 200 kHz. As exceptions, up to five measurements with a 6
level up to the spurious emission limits in Table 4.5.1.3.2-1 are 7
allowed. 8
9
Current region-specific radio regulation rules shall also apply. 10
4.5.2 Radiated Spurious Emissions 11
Current region-specific radio regulation rules shall apply. 12
For example, a Band Class 7 base station operating under US regional requirements shall 13
limit radiated spurious to less than 70 dBW/MHz EIRP in the GPS band from 1559 to 14
1610 MHz. 15
4.5.3 Occupied Bandwidth 16
This test is applicable to Band Class 3 and 6 mobile stations only. 17
4.5.3.1 Definition 18
The occupied bandwidth is defined as the frequency range, whereby the power of emissions 19
averaged over the frequency above and under the edge frequency are 0.5 % each of the total 20
radiation power of a modulated carrier. 21
4.5.3.2 Method of Measurement 22
1. Connect the base station to the mobile station antenna connector as shown in 23
Figure 6.5.1-4. The AWGN generator and the interference generator are not 24
applicable in this test. Connect a spectrum analyzer to the mobile station antenna 25
connector. 26
2. If the mobile station supports demodulation of Radio Configuration 1, 2, 3, 4, or 5, 27
set up a call using Fundamental Channel Test Mode 1 or 3 or Dedicated Control 28
Channel Test Mode 3 (see 1.3) with 9600 bps data rate only and perform steps 4 29
and 5. 30
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3. If the mobile station supports Band Class 6 and demodulation of Radio 1
Configuration 6, 7, 8, or 9, set up a call using Fundamental Channel Test Mode 7 2
or Control Channel Test Mode 7 (see 1.3) with 9600 bps data rate only and perform 3
steps 4 and 5. 4
4. Set the test parameters as specified in Table 4.5.3.2-1. 5
5. Send continuously 0 power control bits to the mobile station. 6
6. Set the resolution bandwidth of the spectrum analyzer to 30 kHz. The value of the 7
occupied bandwidth is calculated by an external or internal computer by summing 8
all samples stored as total power. 9
10
Table 4.5.3.2-1. Test Parameters for Testing Occupied Bandwidth at Maximum RF 11
Output Power 12
Parameter Units Value
Îor dBm/1.23 MHz -104
orc
IEPilot
dB -7
orc
IE Traffic
dB -7.4
13
4.5.3.3 Minimum Standard 14
The occupied bandwidth shall not exceed 1.48MHz for Spreading Rate 1 and 4.6MHz for 15
Spreading Rate 3 (Band Class 6 only). 16
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5 CDMA ENVIRONMENTAL REQUIREMENTS 1
5.1 Temperature and Power Supply Voltage 2
5.1.1 Definition 3
The temperature and voltage ranges denote the ranges of ambient temperature and power 4
supply input voltages over which the mobile station will operate and meet the requirements 5
of these standards. The ambient temperature is the average temperature of the air 6
surrounding the mobile station. The power supply voltage is the voltage applied at the input 7
terminals of the mobile station. The manufacturer shall specify the temperature range and 8
the power supply voltage over which the equipment is to operate. In order to provide a 9
convenient means for the manufacturer to express the temperature range under which the 10
mobile station conforms to these recommended minimum standards, temperature ranges 11
designated by letters are defined in Table 5.1.1-1. 12
13
Table 5.1.1-1. Temperature Ranges 14
Designator Range
A -40°C to +70°C
B -30°C to +60°C
C -20°C to +50°C
D 0°C to +45°C
15
5.1.2 Method of Measurement 16
The mobile station shall be installed in its normal configuration (i.e., in its normal 17
mounting arrangement fully assembled) and placed in a temperature chamber. The 18
temperature chamber shall be stabilized at the manufacturer's highest specified operating 19
temperature, and the mobile station shall be operated over the power supply input voltage 20
range specified by the manufacturer or ±10%, whichever is greater. With the mobile station 21
operating, the temperature shall be maintained at the specified test temperature without 22
forced circulation of air from the temperature chamber being directly applied to the mobile 23
station. The measurements specified in 5.1.3 shall then be performed. 24
Turn the mobile station off, stabilize the mobile station in the chamber at room 25
temperature, and repeat the measurements specified in 5.1.3. 26
Turn the mobile station off, stabilize the mobile station in the chamber at the coldest 27
operating temperature specified by the manufacturer, and repeat the measurements 28
specified in 5.1.3. 29
The overall temperature range may be reduced to a lesser range than -30°C to +60°C if the 30
manufacturer uses circuitry that automatically inhibits RF transmission when the 31
temperature falls outside the lesser range specified. Measurements shall be made at the 32
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specified extremes of the manufacturers temperature range. The manufacturer shall verify 1
that RF transmission is inhibited outside of the specified temperature range. 2
5.1.3 Minimum Standard 3
The mobile station equipment shall meet all of the minimum standards specified in Sections 4
3 and 4 under the standard environmental test conditions specified in 6.2 for all supported 5
band classes. Over the ambient temperature and power supply ranges specified by the 6
manufacturer, the operation of the mobile station equipment shall meet the following 7
minimum standards for all supported band classes unless noted otherwise: 8
1. Receiver sensitivity and dynamic range as specified in 3.5.1.3. The received CDMA 9
power, Îor, used to measure receiver sensitivity may be increased 2 dB at 60°C and 10
higher. 11
2. Frequency accuracy as specified in 4.1.1.3. 12
3. Waveform quality as specified in 4.3.2.3. 13
4. Range of estimated open loop output power as specified in 4.4.1.3. For 14
temperatures outside of the range +15°C to +35°C, the test tolerance lower limit 15
may be relaxed to -12.5 dB. 16
5. Range of closed loop correction as specified in 4.4.4.3. 17
6. Maximum RF output power as specified in 4.4.5.3. For Temperature Range 18
Designators A and B, the ERP for a band classes 0, 2, 3, 5, 7, and 9 mobile station 19
may drop by 2 dB7 at 60°C and higher. For Temperature Range Designators A and 20
B, the EIRP for a band classes 1, 4, 6 and 8 Class II through V mobile station may 21
drop by 2 dB7 at 60°C and higher. These requirements do not apply other than for 22
coldest, room and highest operating temperature test points. 23
7. Minimum controlled output power as specified in 4.4.6.3. 24
8. Conducted spurious emissions as specified in 4.5.1.3. 25
5.2 High Humidity 26
5.2.1 Definition 27
The term high humidity denotes the relative humidity at which the mobile station will 28
operate with the specified performance. 29
7 For the test configuration in 4.4.5.2 where the mobile station is transmitting only on the Reverse Dedicated Control Channel, or only on the Reverse Dedicated Control Channel and 1500 bps Reverse Fundamental Channel, this 2 dB maximum RF output power drop allowance above 60°C is in addition to the allowances in 4.4.5.3 due to the tested channel configurations.
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5.2.2 Method of Measurement 1
The mobile station, after having operated normally under standard test conditions, shall be 2
placed, inoperative, in a humidity chamber with the humidity maintained at 0.024/gm 3
H2O/gm Dry Air at 50°C (40% Relative Humidity) for a period of not less than eight hours. 4
The measurements specified in 3.5.1 (receiver sensitivity and dynamic range) and 4.3.2 5
(waveform quality) shall then be performed. No readjustment of the mobile station shall be 6
allowed during this test. 7
Turn the mobile station off, stabilize the mobile station in the chamber at standard 8
conditions within six hours, and perform the measurements specified in Sections 3 and 4 of 9
this standard. 10
5.2.3 Minimum Standard 11
The mobile station equipment shall meet the minimum standards specified in 3.5.1.3 and 12
4.3.2.3 under the high humidity conditions. Once stabilized in standard conditions, the 13
mobile station shall meet all the minimum standards specified in Sections 3 and 4 of this 14
standard. 15
5.3 Vibration Stability 16
5.3.1 Definition 17
Vibration stability is the ability of the mobile station to maintain specified mechanical and 18
electrical performance after being vibrated. 19
5.3.2 Method of Measurement 20
Sinusoidal vibration at 1.5 g acceleration swept through the range of 5 to 500 Hz at the rate 21
of 0.1 octave/second shall be applied to the mobile station in three mutually perpendicular 22
directions (sequentially) for a single sweep rising in frequency followed by a single sweep 23
falling in frequency. 24
5.3.3 Minimum Standard 25
The mobile station equipment shall meet all the minimum standards specified in Sections 3 26
and 4 after being subjected to the above vibration tests. 27
5.4 Shock Stability 28
5.4.1 Definition 29
Shock stability is the ability of the mobile station to maintain specified mechanical and 30
electrical performance after being shocked. 31
5.4.2 Method of Measurement 32
The mobile station shall be subjected to three test table impacts, in three mutually 33
perpendicular directions and their negatives, for a total of 18 impacts. In all cases, the 34
mobile station shall be secured to the test table by its normal mounting hardware. Each 35
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impact shall be a half sine wave, lasting from 7 to 11 ms, with at least 20 g peak 1
acceleration. 2
5.4.3 Minimum Standard 3
The mobile station equipment shall meet all the minimum standards specified in Sections 3 4
and 4 of this standard and shall not suffer any mechanical damage after being subjected to 5
the above shock tests. 6
7
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6 CDMA STANDARD TEST CONDITIONS 1
6.1 Standard Equipment 2
6.1.1 Basic Equipment 3
The equipment shall be assembled, and any necessary adjustments shall be made in 4
accordance with the manufacturer's instructions for the mode of operation required. When 5
alternative modes are available, the equipment shall be assembled and adjusted in 6
accordance with the relevant instructions. A complete series of measurements shall be 7
made for each mode of operation. 8
6.1.2 Associated Equipment 9
The mobile station equipment may include associated equipment during tests, provided 10
that the associated equipment is normally used in the operation of the equipment under 11
test. For mobile station equipment, this may include power supplies, handsets, cradles, 12
charging stands, control cables, and battery cables. 13
6.2 Standard Environmental Test Conditions 14
Measurements under standard atmospheric conditions shall be carried out under any 15
combination of the following conditions: 16
Temperature: +15°C to +35°C 17
Relative humidity: 45% to 75% 18
Air pressure: 86,000 Pa to 106,000 Pa (860 mbar to 1060 mbar) 19
If desired, the results of the measurements can be corrected by calculation to the standard 20
reference temperature of 25°C and the standard reference air pressure of 101,300 Pa 21
(1013 mbar). 22
6.3 Standard Conditions for the Primary Power Supply 23
6.3.1 General 24
The standard test voltages shall be those specified by the manufacturer, or an equivalent 25
type that duplicates the voltage, impedance, and ampere hours (if relevant for the 26
measurement) of the recommended supply. 27
6.3.2 Standard DC Test Voltage from Accumulator Batteries 28
The standard (or nominal) DC test voltage specified by the manufacturer shall be equal to 29
the standard test voltage of the type of accumulator to be used, multiplied by the number of 30
cells minus an average DC power cable loss value that the manufacturer determines as 31
being typical (or applicable) for a given installation. Since accumulator batteries may or may 32
not be under charge or may be in a state of discharge when the equipment is being 33
operated, the manufacturer shall also test the equipment at anticipated voltage extremes 34
above and below the standard voltage. The test voltages shall not deviate from the stated 35
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values by more than ±2% during a series of measurements carried out as part of a single 1
test on the same equipment. 2
6.3.3 Standard AC Voltage and Frequency 3
For equipment that operates from the AC mains, the standard AC test voltage shall be equal 4
to the nominal voltage specified by the manufacturer. If the equipment is provided with 5
different input taps, the one designated nominal shall be used. The standard test 6
frequency and the test voltage shall not deviate from their nominal values by more than 7
±2%. 8
The equipment shall operate without degradation with input voltage variations of up to 9
±10%, and shall maintain its specified transmitter frequency stability for input voltage 10
variations of up to ±15%. The frequency range over which the equipment is to operate shall 11
be specified by the manufacturer. 12
6.4 Standard Test Equipment 13
6.4.1 Standard Channel Simulator 14
6.4.1.1 Channel Model Parameters 15
The channel simulator shall support the following channel model parameters: 16
All paths are independently faded. 17
The fading is Rayleigh. The probability distribution function of power, F(P), of the 18
signal power level P is: 19
≤>−=
−
0 P 0, 0P,e1)P(F
aveP/P, 20
where Pave is the mean power level. 21
The level crossing rate, L(P) is: 22
≤
>⋅⋅π=−
0P 0, 0P,efP/P2)P(L
aveP/Pdave , 23
where fd is the Doppler frequency offset associated with the simulated vehicle speed 24
given by 25
cd fcvf
= , 26
where fc is the carrier frequency, v is the vehicle speed, and c is the speed of light in 27
a vacuum. 28
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The power spectral density, S(f), is: 1
+≤≤−
−−=
otherwise 0,
,
1
1
)(2
dcdc
dc
fffff
ffffS 2
The autocorrelation coefficient of the unwrapped phase8, ρ(t), is: 3
( )[ ] ( )[ ] ( )[ ]∑∞
=
−− π
π−
π
π+π
π=ρ
1n2
n2d0
2
2
d01
d01
n
tf2J
43tf2Jsin
216tf2Jsin
23)t( , 4
where J0( ) is a zero-order Bessel function of the first kind. 5
This autocorrelation coefficient is shown in Figure 6.4.1-1. 6
-0.2
0.0
0.2
0.4
0.6
0.8
1.0
1.2
0 0.5 1 1.5 2 2.5 3
Lag t in units of 1 / Doppler Frequency
ρρ ρρ(t)
7
Figure 6.4.1-1. Autocorrelation Coefficient of the Phase 8
9
8 The term unwrapped refers to the continuous nature of the phase, that is, with no discontinuities of 2π.
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6.4.1.2 Channel Model Parameter Conditions and Tolerances 1
The following standard conditions and tolerances on the channel model parameters shall be 2
supported by the channel simulator: 3
Vehicle speed, v: 3 km/h for band classes 0, 1, 2, 3, 4, 6, 7, 8, and 9. 4
Vehicle speed, v: 6 km/h for Band Class 5. 5
Vehicle speed, v: 8 km/h for band classes 0, 1, 2, 3, 4, 6, 7, 8, and 9. 6
Vehicle speed, v: 14 km/h for band classes 1, 4, 6 and 8. 7
Vehicle speed, v: 15 km/h for Band Class 5. 8
Vehicle speed, v: 30 km/h for band classes 0, 1, 2, 3, 4, 6, 7, 8, and 9. 9
Vehicle speed, v: 58 km/h for Band Class 5. 10
Vehicle speed, v: 100 km/h for band classes 0, 1, 2, 3, 4, 6, 7, 8, and 9. 11
Vehicle speed, v: 192 km/h for Band Class 5. 12
Power distribution function, F(P): 13
1. The tolerance9 shall be within ±1 dB of calculated, for power levels from 10 dB 14
above to 20 dB below the mean power level. 15
2. The tolerance shall be within ±5 dB of calculated, for power levels from 20 dB 16
below to 30 dB below the mean power level. 17
Level crossing rate, L(P): 18
The tolerance10 shall be within ±10% of calculated, for power levels from 3 dB 19
above to 30 dB below the mean power level. 20
Measured power spectral density, S(f), around the carrier, fc: 21
1. At frequency offsets |f - fc| = fd, the maximum power spectral density S(f) shall 22
exceed S(fc) by at least 6 dB. 23
2. For frequency offsets |f - fc| > 2fd, the maximum power spectral density S(f) 24
shall be less than S(fc) by at least 30 dB. 25
Simulated Doppler frequency, fd, shall be computed from the measured S(f) as 26
( )2/12
cd
df)f(S
dffS)ff(2f
−=
∫∫ 27
9 The tolerance is defined as the error in power expressed in dB, i.e. 10log10(actual/calculated).
10 The tolerance is defined as the error in level crossing rate expressed as the ratio between actual and calculated values.
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Measured autocorrelation function of the unwrapped phase, ρ(t): 1
1. At a lag of 0.05/fd, ρ(t) shall be 0.8 ± 0.1. 2
2. At a lag of 0.15/fd, ρ(t) shall be 0.5 ± 0.1. 3
6.4.1.3 Channel Simulator Configurations 4
The standard channel simulator shall support all the configurations specified in Table 5
6.4.1.3-1. 6
7
Table 6.4.1.3-1. Standard Channel Simulator Configurations 8
9
6.4.2 Waveform Quality Measurement Equipment 10
6.4.2.1 Rho Meter for Radio Configuration 1 and 2 11
When operating in Radio Configuration 1 and 2, the mobile station transmitter generates O-12
QPSK signals as described in Section 2.1.3.1 of [4]. 13
The ideal, complex, transmitter signal is given as 14
tj 0e)t(R)t(s ω= , 15
where R(t) is the complex envelope of the transmitter signal and ω0 is the radian carrier 16
frequency. 17
The samples of R(t) at t = kTs are given as 18
Channel Simulator Configuration
Parameters 1 2 3 4 5 6
Vehicle Speed [km/h]
Band Classes 0, 2, 3, 7, and 9
8 30 30 100 0 3
Band Classes 1, 4, 6 and 8
8 14 30 100 0 3
Band Class 5 15 58 58 192 0 6
Number of Paths 2 2 1 3 2 1
Path 2 Power (Relative to Path 1) [dB] 0 0 N/A 0 0 N/A
Path 3 Power (Relative to Path 1) [dB] N/A N/A N/A -3 N/A N/A
Delay from Path 1 to Input [µs] 0 0 0 0 0 0
Delay from Path 2 to Input [µs] 2 2 N/A 2 2 N/A
Delay from Path 3 to Input [µs] N/A N/A N/A 14.5 N/A N/A
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( ) ( ) ( ) ( ) ( )∑ ∑ φ−−+φ−=n n
nccsncss sin2/TnTkTgjcosnTkTgkTR , 1
where g(kTs) is the unit impulse response of the baseband filter described in Section 2
2.1.3.1.13 of [4]. Tc is the duration of a PN chip, and φn is the phase corresponding to the 3
nth chip, occurring at time tn = nTc , as specified in [4]. The chip rate, 1/Tc , is 1.2288 4
Mcps. The sample rate 1/Ts equals 4/Tc . 5
Modulation accuracy is the ability of the transmitter to generate the ideal signal, s(t). 6
The actual, complex, transmitter waveform is given as 7
( ) ( )[ ] ( )( )τ+ω∆+ω+τ+= tj0 0etE)t(RCtx , 8
where τ is the time offset of the actual transmit signal referenced to the time coordinate of 9
R(t); 0j00 eAC θ= is a complex constant representing the magnitude of the transmitter 10
signal, A0, and arbitrary phase, θ0; ∆ω is the radian frequency offset of the actual carrier 11
relative to the frequency of the ideal carrier; and E(t) is the complex envelope of the error of 12
the actual transmitter signal with respect to the ideal transmitted signal. 13
The time and frequency offset of the actual transmitter signal is corrected by multiplying by 14
a complex factor to produce 15
( ) ( ) ( )[ ]t j 0e txty ω∆+ωτ−= , 16
in which τ and ω∆ are estimates, to the accuracy specified below, of the transmit time 17
offset and the frequency offset of the actual transmitter signal. The radian frequency offset, 18
ω∆ , is converted to frequency offset in Hertz by πω∆=∆ 2/f . 19
The parameters τ , ∆ ˆ ω and θ 0 shall be determined such that the sum-square-error between 20
the reference signal and the signal-under-test is minimized. 21
The ρ-meter shall contain a band-limiting filter. This filter should have less than ±0.1 dB 22
ripple in the passband, and a minimum corner frequency (0.1 dB) of 700 kHz. At 23
frequencies greater than 1.2 MHz, the filter shall have at least 40 dB rejection. The 24
implementation of this filter shall be determined by the ρ-meter manufacturer, consistent 25
with the accuracy requirements specified below. 26
Z(t) denotes the actual output of the filter. 27
Modulation accuracy is measured by determining the fraction of power at the filter output, 28
Z(t), that correlates with the ideal waveform, R(t), sampled at the ideal decision points tk = 29
2(k-1)Ts = (k-1)Tc/2. Modulation accuracy is given in terms of the transmitter waveform 30
quality factor, ρ, defined as 31
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∑ ∑
∑
= =
==ρM
1k
M
1k
2k
2k
2M
1k
*kk
ZR
ZR
, 1
where Zk = Z(tk) is the kth sample of the compensated transmit signal in the measurement 2
interval; Rk = R(tk) is the kth sample of the ideal signal in the measurement interval; and M 3
is the measurement interval in half-chips comprising at least 500 µs for Spreading Rate 1 4
and 167 µs for Spreading Rate 3. 5
The value of ∆ ˆ ω found in minimizing the mean-squared-error for E(t) is the carrier 6
frequency error in radians-Hz. 7
The value of ˆ τ found in minimizing the mean-squared-error for E(t) is the transmit time 8
error in µs. 9
The accuracy of the waveform quality measurement equipment shall be as follows: 10
Waveform quality factor (ρ): ± 0.003 over the range of 0.90 to 1.00. 11
Frequency offset: ± 30 Hz. 12
Transmit time offset: ± 135 ns. 13
The equipment shall be tunable over the applicable bands and be operational over the 14
amplitude range of -50 to +40 dBm. External attenuators and/or amplifiers may be used to 15
meet these power requirements and may be considered as part of the equipment. 16
6.4.2.2 Rho Meter for Radio Configuration 3 through 9 17
When operating in Radio Configuration 3 through 9, the mobile station transmitter 18
generates HPSK signals as described in Section 2.1.3.1 of [4]. 19
6.4.2.2.1 The Ideal Composite Reference Signal 20
A code-channel is established by the Walsh function for that channel, denoted as [ ]kWNm . 21
This represents a Walsh function of length N that is serially constructed from the mth row 22
of a N × N Hadamard matrix. For additional details of the recursive procedure for 23
constructing Walsh functions from Hadamard matrices, see 2.1.3.1.8.1 of [4]. 24
The reference signal for the ( )thN,m code-channel is written as11 25
11 The convention is to use round brackets, ( ), for continuous time and square brackets, [ ], for discrete time. The function x is equal to the largest integer less than or equal to x, and the function
k mod N is equal to the remainder when k is divided by N. xRe denotes the real part of x, and
xIm denotes the imaginary part of x.
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[ ] [ ]NmodkWN/kd]k[R Nm
Nm
Nm = 1
where the integer k corresponds to time; t = kTc, where Tc is the chip interval. [ ]ndNm is the 2
complex data symbol, where [ ] ndRe Nm and [ ] ndIm N
m take on values ± 1, or null (when 3
[ ]ndNm is either purely real or purely imaginary). 4
The ideal, composite, reference signal is given as 5
[ ] [ ] [ ] [ ]∑ β+α=N,m
Nm
Nm
Nm
Nm kRImjkRRekR 6
where the summation is over the values of m,N corresponding to the active code-channels. 7
Nmα and N
mβ correspond to the relative magnitudes of the signals sent to the I and Q-8
channels of the modulator, respectively, for the (m,N)th code-channel. Either Nmα or N
mβ 9
may equal zero, when only the I or Q component of the (m,N)th code-channel is used, and 10
Nmα = N
mβ , when a balanced QPSK signal is transmitted on the code-channel. The range of 11
the time variable, k, extends over a multiple of Nmax, where Nmax is the maximum length of 12
the Walsh functions, and starts and stops at the beginning and end of maximal length 13
Walsh intervals. 14
6.4.2.2.2 The Transmitter Signal-Under-Test 15
The complex envelope, R[k], is scrambled by a complex, pseudo-noise, sequence, P[k], to 16
produce the complex envelope of the ideal, spread-spectrum, signal given as 17
W[k] = P[k] R[k] 18
The ideal transmitter signal is obtained by passing W[k] through a transmitter filter 19
followed by a digital-to-analog converter, reconstruction filter, and upconverter. The filtered 20
and reconstructed baseband signal is written as 21
( ) [ ] ( )ck
kTthkWtS −=∑ 22
where h(t) is the unit-impulse response of a filter for which h[k], specified in Table 23
2.1.3.1.13.1-1 of [4] for Spreading Rate 1 and Table 2.1.3.1.13.2-1 of [4] for Spreading Rate 24
3, is impulse-invariant with values h(k Tc/4) = h(k). 25
The complex transmitter signal-under-test is given as12 26