ShotPro II.022-000058B

Pelton Company, Inc.

C:\V6MAN\SHOTPRO\SPCOV.DOC

SHOT PRO II

01Mar06

P/N 022-000058B

The information contained herein is proprietary to Pelton Company, Inc. The issuance of this sheet does not constitute a right to copy or distribute this material or construct the equipment described herein.


C:\V6MAN\SHOTPRO\SPCOV.DOC

Headquarters:

Pelton Company, Inc. P.O. Box 1415 1500 N. Waverly Ponca City, Ok 74602 Fax: 580.762.0023 Phone: 580.762.6341

Input/Output, Inc. (Houston, TX) 12300 Parc Crest Drive Stafford, TX 77477 Fax: 281.879.3626 Phone: 281.933.3339

Technical support

Email: [email protected] or [email protected]

Access and download the latest Pelton information and upgrades:

• Product information • Firmware releases • Software programs • Training schedule • Manuals and documentation in PDF format

From our World Wide Web site by entering our URL into your Internet browser:

http://www.peltonco.com

World Locations England Input/Output, Inc. Fax: 44.1603.411403 Phone: 44.1603.411400 Russia Igor Skobelev Phone: 7.095.279.1559


01Mar06 C:\V6MAN\SHOTPRO\SPTOC.DOC

SHOT PRO II TABLE OF CONTENTS BASIC SAFETY OVERVIEW........................................... 1.1.1 INTRODUCTION AND SUPPLEMENT INFORMATION......................... 2.1.1 SHOT PRO II FEATURES............................................ 3.1.1 NORMAL OPERATION OVERVIEW....................................... 4.1.1 ADVANCE II ESG OPERATION........................................ 5.1.1 ADVANCE III VIB PRO ENCODER OPERATION........................... 5.2.1 SHOT PRO II ENCODER OPERATION................................... 6.1.1 SHOT PRO II MASTER ENCODER OPERATION............................ 6.2.1 SHOT PRO II SLAVE ENCODER OPERATION............................. 6.3.1 MASTER/SLAVE/REPEATER MODE...................................... 6.4.1 SHOT PRO II COMM MODE........................................... 6.5.1 GPS WITH SHOT PRO II SYSTEM..................................... 6.6.1 SHOT PRO II GPS SET-UP PROCEDURE................................ 6.7.1 SHOT PRO II ENCODER ENTRIES..................................... 7.1.1 SHOT PRO II DECODER ENTRIES..................................... 8.1.1 SHOT PRO II DECODER OPERATION................................... 9.1.1 SHOT PRO II INSTALLATION AND REPAIR............................. 10.1.1 BACKPACK OPTIONS................................................ 11.1.1 SP1FLAGS COMPUTER PROGRAM....................................... 12.1.1 RECORDING TRUCK INTERFACE....................................... 13.1.1 AIR GUN MODE (NOT USED AT THIS TIME)............................ 14.1.1 UPHOLE SIMULATOR OPTION......................................... 15.1.1 SAFETY.......................................................... 16.1.1 DOCUMENTATION................................................... 17.1.1


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Safety Page 1.1.1


01Mar06 C:\V6MAN\SHOTPRO\SPCH01.DOC

PELTON SHOT PRO II SAFETY This equipment is used with explosives; extreme caution should be observed. Do not use this equipment if not familiar with safety regulations.

• Always follow correct procedures described in chapter 16. • Keep everyone away from the Shot point. • Observe local and company safety regulations. • Do not shoot in urban areas. • Do not shoot near power lines. Cap wire can easily come in

contact with power lines after explosion. • Do not shoot close to high power radio transmitters.

After Shot

• Make sure all charges have been detonated • Record and report any shots or caps which were not detonated

Shot Pro II Unit

• High voltage firing line output 400 volt @ 40 amps for 4 mSec • High Voltage output is always electrically shorted together

unless ARM button is pressed.

Safety Page 1.1.2




Intro and Supplement Page 2.1.1



PELTON SHOT PRO II INTRODUCTION The Pelton Shot Pro II (SPII) System is a microprocessor based system for use in seismic exploration to control remotely the firing of explosive charges. The system consists of:

- An Encoder System in the recording truck using either: o Pelton Advance III ESG Vibrator/Shot control unit o Pelton Advance II ESG Vibrator/Shot control unit o SPII Encoder

• Mobile SPII Decoder System at the shot point.

The Mobile SPII Decoder System consists of;

• The SPII Unit with internal Standard GPS.

• Shot Pro II Decode Cable

• A mobile radio (or wireline system).

• 3 each; 12 volt battery

• Backpack with cover

Intro and Supplement Page 2.1.2



SUPPLEMENT The following section explains the most recent changes to the system. The information contained in this section supercedes any conflicting information found later in this manual. Multiple revision documents may be included. This section allows users familiar with the Shot Pro II System to quickly update themselves on the latest features. This section is not currently in use in this first release of the Shot Pro II manual; it is reserved for later releases.

Features Page 3.1.1



PELTON SHOT PRO II DYNAMITE FIRING SYSTEM FOR SEISMIC EXPLORATION

FEATURES:

• Low Power C-Mos Design.

• Compatible with Pelton GPS System and Recording Truck Interface System.

• Interfaces with most commercial radios, using Pelton's field proven radio modulation technique.

• Firing accuracy +- 20 micro seconds (timing error between time break in Encoder and when voltage is applied to cap).

• Graphic display for insuring top performance in the field.

• Operates by radio or wireline link.

• Pelton's Version 5 or 6 ESG and Vib Pro Encoder can be used for both dynamite and vibroseis operation. Allows easy and quick transitions between vibroseis and dynamite operation.

• Uphole geophone digitized at 0.25 or 0.5 mSec sample rate (selectable).

• Automatic and accurate uphole time pick.

• Quality control shot status message automatically returned to recorder.

• Provides an analog output for recording of the uphole signal, and for verifying timing synchronization.

• Shot Pro Computer Program or WinVibSig in Recording Truck allows viewing of uphole signal, verifying time pick, summarizing large numbers of QC records, and downloading all data stored in shooting boxes.

• Encoder and Decoder boxes store up to 500 quality control records, which can be downloaded into a computer at a later time.

• Uphole geophone and Cap Line resistance tests.

• Uphole geophone pulse test.

• Recording System Interface Capabilities in conjunction with VibPro Encoder program.

• Master/Slave Modes.

• Local Fire Capability at Shooting box.

Features Page 3.1.2



HIGH VOLTAGE OUTPUT AND SAFETY FEATURES:

• High voltage Output 400v maximum for 4 mSec maximum.

• Normal output 8 joules.

• Firing pulse automatically terminated after 4 mSec.

• Firing current up to 40 Amps.

• High Voltage Outputs are always electrically connected together unless the ARM button is pressed.

• Each Shot Pro Shooting Box can be addressed individually.

Inappropriate boxes will not fire even if ready when a shot command is sent. Alternatively, system can be configured so that any box will fire when a command is sent.

• High security from unauthorized use. Communications with a Pelton

Start Code Generator required for actual detonation of charges.

• Double safety design preventing unintentional or unexpected detonation unless at least two hardware devices fail.

• Common mode protection from electrical impulses on the firing and

uphole lines. SPECIFICATIONS:

• Operating Temperature Range: -40° C to +60° C

• Input voltage: 10 - 36 V for control circuitry 10 - 36 V for high voltage circuitry Reverse polarity

• Current: 1.2 Amps charging

0.26 Amps normal operation

• Size: 4.00" (102mm) x 11.00" (279mm) x 6.00" (152mm)

• Weight: 5.2 Pounds (2.4 Kilograms)

Operation Page 4.1.1


01Mar06 I:\LISD Manuals\Pelton\ShotPro 2\SPCH04.DOC

Normal Operation Overview of Shot Pro II System:

• The operator of the mobile system (the Shooter) first finds the cap location and follows the safety guidelines similar to those outlined in the safety section of this manual.

• The Shooter then records the position of the shot with the GPS

receiver. This is done by using the keypad and display on the front panel of the SPII Unit.

• The flag number used for this shot point is then selected or entered

on the SPII Unit.

• The geophone and cap leads are then connected to the SPII unit and impedance of each line is tested using the Test Menu of the SPII Unit.

• After verification of geophone and cap connections, the cap lines

should be shorted together to avoid accidental explosion.

• The Shooter then waits for the Observer in the Recording Truck to signal him that he is ready for the shot.

• When the Observer is ready, the shooter connects the cap leads to

the SPII Unit and again tests for proper connection.

• The Shooter makes sure he is not touching the high voltage lines, enters the Arm Mode and presses the charge and arm buttons on the SPII unit.

• When the SPII is charged and ready, the unit can automatically

notify the Recording Truck or the Shooter can manually notify the observer verbally.

• The Advance II ESG, VibPro ESG or SPII Encoder, in the recording

unit, then sends a start code over the radio (or wireline) to initiate the blast.

• The SPII Unit receives this code and compares the unit's start code,

crew ID # and ID # with the start code, crew ID # and ID # transmitted. If they match, the unit fires the cap.

• The SPII records and stores the Analog geophone signal and determines uphole time.

• The SPII Unit then automatically sends all information back to the

Recording Truck.

Operation Page 4.1.2



• Exactly 1 second after the blast, a pulse appears on the Analog output of the Encoder which confirms the reception of the digital message from the SPII Unit. This signal is called Decoded Clock Time Break.

• At 1.5 seconds the Confirmation Time Break signal appears.

• At 2.0 seconds the Analog uphole signal is reproduced.

• The computer in the recording truck will display the uphole signal,

the uphole time pick, GPS position, flag number, results of all tests, and other critical parameters. There is also a comment field for the Observer to enter data (like tape and file number) to the record. All of the data is stored to disk with a time and date stamp for later analysis. The Shot Pro Software program allows the shots to be reviewed and comments to be edited.

• The data is also automatically stored, up to 500, in the Encoder and

Decoder SPII Unit and can be downloaded at the day’s end.

ESG Operation Page 5.1.1



ADVANCE II ESG OPERATION The Advance II ESG can be used to control both vibroseis and dynamite operation. Refer to Advance II ESG Manual for more detailed information on installation and operation. This text explains the requirements for using the Advance II ESG with the Shot Pro II System. REQUIREMENTS:

Advance II ESG Version 5 or 6 Version 5H or 6C Firmware or later Computer Communication System Vibra*Sig Module must be modified for high baud rate option.

ESG Set Up for Shot Pro II

• Enter Sweep type 500 for SPII operation. • Select vibrator number to match SPII unit ID number. Setting the

vibrator number to 15 enables all Shot Pro Units. • Select sweep number to match SPII Decoder Crew ID number. Use

sequence number thumbwheel to select proper sweep number. • Enable the vibrator start switch to allow the SPII's ready tone to

fire the ESG. • Load the special Stored Values sweep if timing marks are desired.

See SPII sweep at end of this section. • Select correct Stored Values sweep number. • Set ESG to Stored Values Mode.

Start Time Test: To adjust start time compare the time break of the ESG to the high voltage output of the SPII. Use Selection 6 on ESG to align the time break signals. RADIO REF DELAY The Radio Reference in the ESG can be used to provide timing marks for the following signals on the Radio Vib line (See Fig. 1 page 5.1.5):

• Decoded Clock Time Break (1.0 sec.) • Conformation Time Break (1.5 sec.) • Uphole Signal (2.0 sec.)

After setting up Selection 6 with the Start Time Test, use selection 20 to delay the Radio Reference pulse at one second to align with the Decoded Clock Time Break signal on the Radio Vib line.




ANALOG CONFIRMATION AND UPHOLE SIGNALS The Advance II ESG and the SPII Encoder both output an analog signal to the Recording System for Confirmation of proper Decoder operation. Three signals Decoded Clock Time Break, Confirmation Time Break and the Uphole Signal are time multiplexed on this one analog line. (See Fig. 1 page 5.1.5 and Fig. 2 page 7.1.13) DECODED CLOCK TIME BREAK This signal appears on the analog line at about 1 second. It corresponds to the Application of voltage to the cap terminals at the decoder. This signal is decoded from the returning PFS (Post Fire Service) data from the Decoder. If the Decoder fires late this signal will be delayed, if the Decoder fires early this signal will be early. Confirmation Time Break and Uphole Signal are delayed by .5 and 1 sec after Decoded Clock Time Break as a reference, respectively. CONFIRMATION TIME BREAK The Confirmation Time Break pulse occurs exactly 0.5 sec plus Confirmation Time Break delay after the Decoded Clock Time Break. The Confirmation Time Break Delay is defined as the amount of time between when the Fire Pulse occurs and the current starts flowing over 4 amps. If the current does not flow by the end of fire time (4 mSec), then this pulse will not occur. If this happens, the Decoder assumes the cap did not fire. UPHOLE SIGNAL The analog Uphole Signal recorded by the Decoder is reproduced exactly 1.0 second after the Decoded Clock Time Break Signal. ALTERNATING VIBRATOR/DYNAMITE OPERATION Set all vibrator units to a different start code than the Shot Pro Units. For the dynamite operation select a sweep number with sweep type set to 500. Use an unused vibrator sequence number for dynamite operation. For example Sequence O is used for vibrator operation. It selects start code O and a sweep number 1. Sweep number 1 has the Vibrator Production sweep. Sequence 1 is used for dynamite. It selects start code 1 and sweep number 2. Sweep number 2 is used for dynamite shooting. Sweep number 2 uses sweep type 500. The vibrator number of 15 can be set to enable all Shot Pro Units. Several sequence numbers can be used to address individual Decoder Units.




Wire Line Communications Communications between an Advance II Encode Sweep Generator or SPII Encoder and SPII Decoder(s) may be accomplished by wire rather than by radio. To do this, connect pins A and B of the five pin radio connector together and connect them to one wire in the cable to be used for communication. Connect pins C and E of the five pin radio connector together and connect them to another wire in the communication cable. Wire line communications should be satisfactory over several miles of cable. There are no provisions for voice communications through the SPII‘s, but using the paralleling intercom units on the same wire pair should not cause a problem.

Shot Pro II Sweep Definition To make a Stored Values sweep for Version 5 ESG’s in SPII operation, define the sweep as follows:

Notes:

The amplitude for Amplitude Segment 0 and the lengths of Amplitude Segments 1 and 3 are different for Version 5 and Version 6 sweeps. Link Definition is not used for Version 5 equipment.

No ESG Configuration changes (including bypassing filter channels) are necessary for accurate timing when using these sweeps.

Frequency Definition: FSeg# Start: End: Length: Type: Constant: C/N Phase 0 0 0 3 L 0 [] 90

Amplitude definition: (must define 3 segments) ASeg# Up Taper: Dn Taper: Start%: End%: Length: 0 0 0 95 95 .0055

Change to Amplitude Segment 1. ASeg# Up Taper: Dn Taper: Start%: End%: Length: 1 0 0 0 0 .9916



Segment Definition: Seg# Frequency: Length: 3 Amplitude: Length: 3 10 0 01020203 (Segment 10 is recommend but use any segment you want.)




To make a Stored Values sweep for Version 6 ESG’s in SPII operation, define the sweep as follows: Notes:

The amplitude for Amplitude Segment 0 and the lengths of Amplitude Segments 1 and 3 are different for Version 5 and Version 6 sweeps. Link Definition is not used for Version 5 equipment. No ESG Configuration changes (including bypassing filter channels) are necessary for accurate timing when using these sweeps.

Frequency Definition: FSeg# Start: End: Length: Type: Constant: C/N Phase 0 0 0 3 L 0 [] 90 Amplitude definition: (must define 3 segments) ASeg# Up Taper: Dn Taper: Start%: End%: Length: 0 0 0 95 95 .0055 Change to Amplitude Segment 1. ASeg# Up Taper: Dn Taper: Start%: End%: Length: 1 0 0 0 0 .9931 Change to Amplitude Segment 2. ASeg# Up Taper: Dn Taper: Start%: End%: Length: 2 0 0 0 0 .4945 Change to Amplitude Segment 3. ASeg# Up Taper: Dn Taper: Start%: End%: Length: 3 0 0 0 0 .9959 Segment Definition: Seg# Frequency: Length: 3 Amplitude: Length: 3 10 0 01020203 (Segment 10 is recommend but use any segment you want.) Link Definition (not used with Ver. 5 equipment): Sweep# = your choice Sweep Link Definition: Sweep# Sweep Link Definition: Your choice 10 (Use the same SEG# in the Segment Definition step above)

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Page 5.1.5

Vib Pro Operation Page 5.2.1


01Mar06 I:\LISD Manuals\Pelton\ShotPro 2\spch052.doc

ADVANCE III VIB PRO ENCODER OPERATION The Advance III Encoder can be used to control both vibroseis and dynamite operation. Refer to Advance III Vib Pro Manual for more detailed information on installation and operation. This text explains the requirements for using the Advance III Encoder with the SPII System. Encoder Set Up for Shot Pro II • Disable Radio Similarity. • Select ID number to match SPII unit ID number. • Select the special S.P. sweep type 6 (ShotP) if timing marks are

desired. • Set crew number and start code number in encoder to match SPII Unit.

An entry of 15 in crew number at Decoder enables starts with all selected crew numbers.

Start Time Test: The SPII radio interface in the VPRO Mode is identical to the Advance III vibrator electronics. If the SPII is using the same radio and connection as the Vibrator Electronics then the start time should be identical. To adjust start time compare the time break of the ESG to the high voltage output of the SPII. Use Encoder delay entry in the Encoder to align the time break signals. RADIO REF DELAY The Radio Reference in the Encoder can be used to provide timing marks for the following signals on the Radio Vib line (See Fig. 5 page 5.2.5):

• Decoded Clock Time Break (1.0 sec.)

• Conformation Time Break (1.5 sec.)

• Uphole Signal (2.0 sec.) After setting up Encoder delay with the Start Time Test, Radio Reference Delay to delay the Radio Reference pulse at one second to align with the Decoded Clock Time Break signal on the Radio Vib line. ANALOG CONFIRMATION AND UPHOLE SIGNALS The Advance III Encoder and the SPII Encoder both output an analog signal to the Recording System for Confirmation of proper Decoder operation. Three signals Decoded Clock Time Break, Confirmation Time Break and the Uphole Signal are time multiplexed on this one analog line. (See Fig. 5 page 5.2.5 and Fig. 2 page 7.1.13)

Vib Pro Operation Page 5.2.2


01Mar06 I:\LISD Manuals\Pelton\ShotPro 2\spch052.doc

DECODED CLOCK TIME BREAK This signal appears on the analog line at about 1 second. It corresponds to the Application of voltage to the cap terminals at the decoder. This signal is decoded from the returning PFS (Post Fire Service) data from the Decoder. If the Decoder fires late this signal will be delayed, if the Decoder fires early this signal will be early. Confirmation Time Break and Uphole Signal are delayed by .5 and 1 sec after Decoded Clock Time Break as a reference, respectively.

CONFIRMATION TIME BREAK The Confirmation Time Break pulse occurs exactly 0.5 sec plus Confirmation Time Break delay after the Decoded Clock Time Break. The Confirmation Time Break Delay is defined as the amount of time between when the Fire Pulse occurs and the current starts flowing over 4 amps. If the current does not flow by the end of fire time (4 mSec), then this pulse will not occur. If this happens, the Decoder assumes the cap did not fire.

UPHOLE SIGNAL The analog Uphole Signal recorded by the Decoder is reproduced exactly 1.0 second after the Decoded Clock Time Break Signal.

ALTERNATING VIBRATOR/DYNAMITE OPERATION Set all Vib Pro Units and SPII Units to unique ID numbers. By placing only the desired ID numbers in the active Vib group any combination of Vibrator only, SPII only or both can be selected. In addition the start code or crew number can be used to identify unique boxes.

For example Sequence 1 is used for vibrator operation. It selects start code O, a sweep #1, crew #15 and Group A. Sweep #1 has the Vibrator Production sweep.

Sequence 2 is used for dynamite. It selects start code 1 and sweep #2, crew #1 and Group B. Sweep number 2 is used for dynamite shooting.

Sweep #2 uses sweep type = SHOTP. In this example the selected SPII ID# is only in Group B. Several sequence numbers can be used to address individual Decoder Units. Wire Line Communications Communications between an Advance III Encoder or SPII Encoder and Decoder(s) may be accomplished by wire rather than by radio. To do this, connect pins A and B of the five pin radio connector together and connect them to one wire in the cable to be used for communication. Connect pins C and E of the 5 pin radio connector together and connect them to another wire in the communication cable. Wire line communications should be satisfactory over several miles of cable. There are no provisions for voice communications through the Shot Pros, but using the paralleling intercom units on the same wire pair should not cause a problem.

Encoder 6.1.1



SHOT PRO II ENCODER OPERATION MANUAL RE-ARM OPTION

1) Press and hold "ARM" button about 3 seconds to turn unit ON.

ENCODER MODE

A FIRE

C DATA ENTRY

D SHOT HISTORY

E RADIO MODE

AUTO ARM=OFF OFF Clr BATTERY = 12.25Volt

2) Make sure unit is in Encoder Mode. If not press "C" to enter the

Data Entry menu. Use the up and down arrow keys to move the highlight bar to "1" and press "Ent" to enter the Job Profile menu. Move the bar to "3", then use the left or right arrow key to change the box mode to Enc, then press "E" on the following screen. Press "B" to return to the main menu.

3) From main menu press "A" to enter fire menu.

ENCODER MODE

A FIRE

DECODER Num =10 CREW Num =15 START CODE = 1

REMOTE FIRE =ON AUTO ARM =OFF B RETURN

Encoder 6.1.2



4) Set CREW # and START CODE # to match the Decoder unit to be controlled. Entering a value of 15 at the Encoder unit in DECODER # or CREW # is an override of the corresponding parameter in the SPII decoders i.e. - Entering DECODER #15, enables all SPII Units with matching CREW #

and on the selected start code. - Entering CREW #15 enables all SPII units with matching START CODE

and DECODER #. The above parameter bypass feature should be used cautiously with experienced shooting crew only since it may potentially cause multiple decoder units to fire on a single start code transmission. As to set these parameters use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing enter after selection will enter number and advance to next selectable entry line. The Remote Fire and Auto Arm modes must be changed in the Data Entry menu under the Hardware setup menu.

5) Wait for the shooter to notify the recorder that he is ready and it is safe to fire the shot.

6) Arm the Encoder by pressing the up arrow key. 7) Verbally inform the Shooter that the Start command is coming. 8) Start the Recorder System.

Encoder 6.1.3



Automatic Re-Arm Option The SPII Encoder will automatically re-arm after a firing sequence if the AUTO ARM is turned "On". In this mode of operation, the SPII Encoder will accept a start command from the recording system any time after the Fire Mode is initially entered. The sequence of events for this mode of operation is: 1) Press and hold the "ARM" button about 3 seconds to turn the unit ON.

ENCODER MODE

A FIRE

C DATA ENTRY

D SHOT HISTORY

E RADIO MODE

AUTO ARM=ON OFF Clr BATTERY = 12.25Volt

2) Make sure unit is in Encoder Mode. If not press "C" to enter the

Data Entry menu. Use the up and down arrow keys to move the highlight bar to "1" and press "Ent" to enter Job Profile menu. Move the bar to "4", then use the left or right arrow key to change the box mode to Enc, then press "E" on the following screen. Press "B" to return to the main menu.

3) From Main Menu, press "A" to enter the Fire Menu.

ENCODER MODE

A FIRE


REMOTE FIRE =ON AUTO ARM =ON B RETURN

Encoder 6.1.4



4) Set CREW # and START CODE # to match the Decoder unit to be controlled.

Entering a value of 15 at the Encoder unit in DECODER # or CREW # is an override of the corresponding parameter in the SPII decoders i.e. - Entering DECODER #15, enables all SPII Units with matching CREW #

and on the selected start code. - Entering CREW #15 enables all SPII units with matching START CODE

and DECODER #. The above parameter bypass feature should be used cautiously with experienced shooting crew only since it may potentially cause multiple decoder units to fire on a single start code transmission. As to set these parameters use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing enter after selection will enter number and advance to next selectable entry line. The Remote Fire and Auto Arm modes must be changed in the Data Entry menu under the Hardware setup menu.

5) Press the "A" button to enable firing.

MANUAL FIRE ^



6) Wait for the shooter to notify the recorder that he is ready and it

is safe to fire the shot.

7) Arm the Encoder by pressing the up arrow key. 8) Verbally inform the shooter that the start command is coming. 9) Start the recording system. 10) Return to step 6. (The SPII Encoder will automatically get ready for

the next shot after the current firing sequence is completed.) To change Fire Menu items, press the "B" key, then go to step 3.

Master Encoder 6.2.1


01Mar06 I:\LISD Manuals\Pelton\ShotPro 2\SPCH062.doc

SHOT PRO II MASTER ENCODER OPERATION The Master Encoder is the primary control of the shot. Its settings DECODER # and CREW # will be retransmitted by the Slave Encoder to the Decoder assuming that the Start code of the Master Encoder matches both the Slave Encoder and the Decoder. MANUAL RE-ARM OPTION 1) Press and hold "ARM" button about 3 seconds to turn unit ON.

ENCODER MODE MASTER

A FIRE

C DATA ENTRY

D SHOT HISTORY

E RADIO MODE


2) Make sure unit is in Master Encoder Mode. If not in Master Encoder

Mode, press "C" to enter the Data Entry menu. Use the up and down arrow keys to move the highlight bar to "1" and press "Ent" to enter the Job Profile menu. Move the bar to selection "4", use the left and right arrow keys to toggle thru the menu Off/Master/Slave. Press "B" to return to main menu.


ENCODER MODE MASTER

A FIRE






4) Set CREW # and START CODE # to match the Decoder unit to be controlled.

Entering a DECODER #15 at the Encoder unit in or a CREW #15 is an override of the corresponding parameter in the SPII decoders i.e. - Entering DECODER #15, enables all SPII Decoder Units with

matching CREW # and start code. - Entering CREW #15 enables all SPII Decoder units with matching

START CODE and DECODER #. The above parameter bypass feature should be used cautiously with experienced shooting crew only since it may potentially cause multiple decoder units to fire on a single start code transmission. The above applies if the Master Encoder/Recorder is controlling the Firing sequence. As to set these parameters use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing enter after selection will enter number and advance to next selectable entry line. The Remote Fire and Auto Arm modes must be changed in the Data Entry menu under the Hardware setup menu. Use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing enter after selection will enter number and advance to next selectable entry line. The Remote Fire and Auto Arm modes must be changed in the Data Entry menu under the Hardware setup menu.


6) Arm the Master Encoder. 7) Start Recorder System.




Automatic Re-Arm Option The SPII Encoder will automatically re-arm after a firing sequence if the Auto Arm is turned "On". In this mode of operation, the SPII Encoder will accept a start command from the recording system any time after the Fire Mode is initially entered. The sequence of events for this mode of operation is: 1) Press and hold the "ARM" button about 3 seconds to turn the unit ON.

ENCODER MODE MASTER

A FIRE

C DATA ENTRY

D SHOT HISTORY

E RADIO MODE


2) Make sure unit is in Master Encoder Mode. If not in Master Encoder

Mode, press "C" to enter the Data Entry menu. Use the up and down arrow keys to move the highlight bar to "1" and press "Ent" to enter the Job Profile menu. Move the bar to selection "4", use the left and right arrow keys to toggle thru the menu Off/Master/Slave. Press "B" to return to main menu.

3) From Main Menu, press "A" to enter the Fire Menu.

ENCODER MODE MASTER

A FIRE






4) Set CREW # and START CODE # to match the Decoder unit to be controlled. Entering a DECODER #15 at the Encoder unit in or a CREW #15 is an override of the corresponding parameter in the SPII decoders i.e. - Entering DECODER #15, enables all SPII Decoder Units with

matching CREW # and start code. - Entering CREW #15 enables all SPII Decoder units with matching

START CODE and DECODER #. The above parameter bypass feature should be used cautiously with experienced shooting crew only since it may potentially cause multiple decoder units to fire on a single start code transmission. The above applies if the Master Encoder/Recorder is controlling the Firing sequence. As to set these parameters use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing enter after selection will enter number and advance to next selectable entry line. The Remote Fire and Auto Arm modes must be changed in the Data Entry menu under the Hardware setup menu.

5) Press the "A" button to enable firing.

MANUAL FIRE ^




7) Arm the Master Encoder.

8) Verbally inform the shooter that the start command is coming.

9) Start the recording system.

10) Return to step 6. (The SPII Master Encoder will automatically get ready for the next shot after the current firing sequence is completed.)

To change Fire Menu items, press the "B" key, then go to step 3.

Slave Encoder 6.3.1



SHOT PRO II SLAVE ENCODER OPERATION MANUAL RE-ARM OPTION

1) Press and hold "ARM" button about 3 seconds to turn unit “ON”.

ENCODER MODE SLAVE

A FIRE

C DATA ENTRY

D SHOT HISTORY

E RADIO MODE


2) Make sure unit is in Slave Encoder Mode. If not in Slave Mode,

press "C", then move the highlight bar using the up and down arrow keys to “1” and press “Ent” to enter Job Profile menu. Then move the bar to selection “4”. When on selection “4” use the left and right arrow keys to toggle through the selections OFF/Master/Slave until you get to Slave. Press “B” to return to main menu.


ENCODER MODE SLAVE

A FIRE



4) Select START CODE # to match the Master Encoder unit and the SPII Decoder.

If started from the Master Encoder the DECODER # and CREW # retransmitted to the Decoder will be the ones received from the Master Encoder. If started from the Slave Encoder the DECODER # and the CREW # of the Slave Encoder will be selecting the corresponding SPII Decoder unit. Use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing enter after selection will enter number and advance to next following line. The Remote Fire and Auto Arm modes must be changed in the Job profile menu.

Slave Encoder 6.3.2



5) Arm the Slave Encoder.

SLAVE

MANUAL FIRE ^


REMOTE FIRE =OFF AUTO ARM =ON B RETURN

6) Remote Fire must be OFF in slave Encoder mode. Refer to Hardware

Setup procedure to set Remote Fire to the OFF condition.

Master/Slave 6.4.1



MASTER/SLAVE and REPEATER MODES The SPII unit can be used as a Master Encoder, a Slave Encoder or a Repeater. The Repeater Mode is identical to the Slave Mode except the Repeater does not have a Recording System attached. In the Master/Slave/Repeater Mode (See Figure 3 page 6.4.3) the Master Encoder receives a start from the recording system then sends the Master Start Code. The Master START CODE consist of a BOX ID # and a CREW ID #. For the Slave/Repeater to receive these codes the Slave/Repeater must be set to the same START CODE as the Master. After the Slave/Repeater receives the Master START CODE, the slave outputs a pulse on the RecStart line to start the Slave Recorder. The Slave/Repeater unit will then send Start Codes to the Decoder unit. The same Start Code, Box ID # and Crew ID # which were transmitted by the Master are now sent to the Decoder units. If both the Master and Slave/Repeater are in radio range of the Decoder, then both will receive the PFS uphole Message from the Decoder. After the Slave/Repeater has received the PFS data, the Slave/Repeater will retransmit the PFS data to the Master unit. The retransmitted uphole data will appear on the analog output of the Master unit at 2.5, 3.0 and 3.5 seconds.

mgray

Page 6.4.2

Master/Slave 6.4.2




Mode Page 6.5.1



Shot Pro II Comm Mode Decoder Operation: Press "C", to enter the Data Entry Menu, use the up and down arrow keys to move the highlight bar to selection “1” the Job file menu and press “Ent”. Move the bar to “5” and use the left and right arrow keys to select the Comm Mode – ShotPro/Adv II/VibPro. Press "B" to return to main menu. In ADVII mode the SPII decoder accepts the AdvanceII start code and will send the PFS in AdvanceII format. In SHOTPRO mode the SPII decoder accepts AdvanceII Start Code and will send the PFS in VibPro format. In VIBPRO mode the SPII decoder accepts the Vib Pro Start Code and will send the PFS in VibPro format. The Shot pro Mode gives the capability for the SPII Decoder to detect weaker Start Code signal than the Vib Pro Mode and provides the Encoder with better PFS retrieval capability than the ADVII Mode. Note: At the time of this release the Air Gun Mode was not fully implemented (expected Air Gun mode completion at end 2003).

Mode Page 6.5.2




GPS Page 6.6.1



GPS with Shot Pro II System The SPII has a built-in GPS receiver. Alternately an external GPS receiver can be used with the SPII Decoder to record Shot Hole positions. The external GPS receiver must have the following features:

• Has RS232 Serial Data Interface to communicate with the SPII at 9600 or 4800 Baud, N-8-1.

• Provide NMEA-0183 Standard VTG, GGA and GSA output messages. • Capable of receiving corrections

DGPS Operation A built in modem system is provided with the SPII System to receive the RTCM SC-104 differential corrections. The SPII Decoder will automatically demodulate the differential correction data from a Pelton Radio Modem or an RCC module. The differential correction can also be generated by the SPII Encoder acting as a Reference Station (Single Radio mode of operation) without conflicting with the normal shooting operation.

Single Radio Option The single radio option allows GPS correction data and SPII control data to be transmitted on one radio frequency. The SPII Encoder transmits the RTCM corrections. The SPII Decoder will receive this data and serially transmit it to the GPS receiver. RTK Operation The SPII is capable of receiving the $PTNL, GGK message. The SPII will send the RDOP for the HDOP and the Quality Indicator byte from the GGK message in the GPS PFS message. GPSMAP version 4.42 and newer will store the Quality Indicator in the SEG-P1 file. The RTK GPS receiver will need a separate radio link for the RTK correction data.

Normal DGPS Operation In normal GPS operation the position of the Shot Hole is recorded before the Shot is fired. The shooter performs the following steps to record the position.

• Position the SPII Decoder with internal/external GPS at the Shot Point. • Select GPS Menu on SPII Decoder. • Select start by pressing the left arrow key on the GPS Menu to receive

GPS position. • If not operating in Single Radio mode, select the Radio frequency,

which is used for transmitting the differential correction information. The SPII will demodulate this signal and send it to the GPS receiver. The GPS position will be displayed on the front panel.

GPS Page 6.6.2



The SPII Decoder LEDs will show the status of the received position as follows:

Left LED Right LED Status description Red Off No GPS position received Off Red GPS Position received invalid Red+Green Red+Green Non-Differential 2-D position Green Red+Green Non-Differential 3-D position Red+Green Green Differential 2-D position Green Green Differential 3-D position

- If the GSA message is present the PDOP, HDOP and VDOP will be

displayed below the GPS position. - The bottom line of the GPS will use the symbol “*” to indicate

the number of satellites visible. • Press the right arrow key “stop” to stop the GPS data acquisition and

save the position in memory. • If not in Single Radio mode select the radio frequency used for seismic

operation. • Return to the Main Menu on SPII.

After firing the Shot the position information will be returned along with the Uphole data in the PFS.

Prior to the Shot the GPSMAP program can perform a position request. The Advance II ESG and the Pelton Monitor Module support the position request message in AdvII mode. The A3 protocol (Vib Pro) position request message has to be transmitted through the Vib Pro Encoder or the SPII Encoder. Multiple decoders can be selected for position request with the A3 protocol. The Memory Load selection must be set to “ON” to allow the position request in the decoder(s). Navigation Operation The Shooter can navigate to serially loaded flags. The Shooter performs the following steps to load the flags: • From the GPS menu select the FLAGS menu on SPII Decoder. • Connect the 9-pin connector labeled “Computer” to the computer running

SP1FLAGS. • Send the flag data to the SPII Decoder with SP1FLAGS. • Disconnect the 9 pin "computer" cable. • The bottom of the display will show how many flags were loaded. • The SPII Decoder is ready for Navigating.

GPS Page 6.6.3



The Shooter performs the following steps to Navigate with the SPII Decoder: • Select the GPS Menu on the SPII Decoder. • Use the up and down arrow keys to scroll through the loaded navigation

flags. Scroll up and down until desired flag is found or enter the desired flag number then press “Enter”. If found, the flag number will be highlighted on the screen. Press “Enter” one more time. The unit will go to the GPS menu. Select NAVIGATION to go to the navigation menu.

• If not in the Single Radio mode select the Radio frequency that is used for transmitting the Differential Correction information. The Shot Pro will demodulate this signal and send it to the GPS receiver.

• Navigate to the flag. The assumption is that the SPII decoder is carried in the ventral position by the shooter or in front of the vehicle used to move between shot points. When moving the black arrow of the navigation screen will show the direction to the selected flag. Information about azimuth, distance to the flag and motion speed are also displayed. The bottom line of the display uses the “*” symbol to indicate the number of visible satellites. The LED’s also help to navigate.

Left LED Right LED Indication meaning Flashing Green Go left Flashing Green Go right Flashing Green Flashing Green Go straight Solid Green Solid Green Flag within 5 Meter Red Go to the opposite direction Red Go to the opposite direction

• Press stop on the GPS Menu. • If not in the Single Radio mode select the radio frequency used for

seismic operation. • Return to Main Menu on SPII unit.

GPS Page 6.6.4




GPS Page 6.7.1



PELTON SUB-METER and Standard GPS Receivers Shot Pro II Set-Up Procedure

The SPII has an internal GPS receiver. The standard equipment includes a Furuno GN-79N. If ordered with a sub-meter unit it will be equipped with a Novatel OEM4. The later can operate as a raw GPS unit or as a reference station. Furuno GN-79N and Novatel OEM4 receivers set-up procedure

- Set the SPII in Decoder mode - Press “C” to go to the Data Entry menu - Use the up or down key to move the highlight to Hardware Set-Up

(line 6) - In the Hardware Set-Up menu move the highlight to GPS Mode (line 7) - Use either the left or right arrow to change the GPS mode to IntGPS - Use either the left or right arrow to change the GPS mode to SetGPS

and depress the “Enter” key. The screen will show the GPS Set-Up menu

Furuno GN-7N set-up

- Set the serial Baud rate to 4800. - Connect the 9 pin “D” connector labeled GPS to the computer serial

port. - On the computer run NMEAmoni(E2).exe program - Select the available COM port number and click Start

- For proper operation the GPS unit should output GGA, GSA and VTG messages.

- To enable GGA message type: SPFEC,GPint,GGA01,CR.LF. In the command window and click “Send”. Note: The command is case sensitive.

GPS Page 6.7.2



- Click Clear_screen. The GGA message should show on the screen. - To enable the GSA message type: $PFEC,Gpint,GSA01,CR.,LF.

In the command window and click “Send”. Note: The command is case sensitive

- Click Clear_screen. The GSA message should be displayed on the screen.

- To enable the VTG message type: $PFEC,Gpint,VTG01,CR.,LF. In the command window and click “Send”. Note: The command is case sensitive

- Click Clear screen. The GSA message should be displayed on the screen.

- To disable any message type: $PFEC,GPint,(message name)00,CR.,LF. In the command window and click “Send”. Note: The command is case sensitive. i.e. $PFEC,GPint,DTM00,CR.,LF. The GPS receiver will output the DTM message once and then disable it.

GPS Page 6.7.3



Novatel OEM4 Set-Up SPII Decoder setup (cont’d)

- Set the serial Baud rate to 9600. - Connect the 9 pin “D” connector labeled GPS to the computer serial

port.

A CD ROM is shipped to our customers with each NovAtel OEM4 receiver. The documentation and programs mentioned in this document for the OEM4 are on that CD.

The OEM4 has multiple capabilities. The commands pertaining to this unit can be found in the Novatel Manual Volume 2. This instruction set is only intended for a quick introduction to the set-up.

The OEM4 responds to commands that are issued over the serial link in an ASCII format (text).

Using the gpssolution4, which is a Novatel program, command lines can be entered and data monitored in the ASCII messages window of the same program.

After starting gpsolution4.exe select: -Device\Open

The Open window appears. If no device configuration has been previously created select New.

Else re-use the same configuration.

GPS Page 6.7.4



The New Config window opens. Enter a name for the new configuration. Click on Settings (Serial).

Select the desired serial port and set the Baud rate to 9600. Click off the Hardware handshaking tab.

Click OK on the Serial Device Settings and the New Config windows. Then Open the device using the newly created configuration.

GPS Page 6.7.5



The program will attempt to connect to the GPS unit.

If the connection cannot be established the error message below will show. Verify the serial connection (standard Pelton RS232 null modem cable) between the PC and the connector of the SPII.

When a good communication link is established the gpssolution4 will show the acknowledge of the GPS card as shown below.

Entry of commands can be done in the edit window, which is at the bottom of the Console window. If the Console window does not automatically open when starting the program, click on View, then Console Window. It may be necessary to enlarge the main window for the program and also the Console sub-window in order to be able to see the edit window. An example of a command “unlogall” is in the graphic below. After entering the command, click on the Enter button or press the Enter key from the keyboard of your computer.

Note: Commands are not case sensitive

GPS Page 6.7.6



If the command is successful the display will echo the command as shown above else in case of an illegal entry the display will return the message below generally indicating a typo error.

GPS Page 6.7.7



Rover Mode Setup: A typical set-up for a rover station (SPII decoder) will include the following commands. Unlogall fix none Interfacemode com1 rtcm novatel log com1 gpgga ontime 1.0 log com1 gpgsa ontime 1.0 log com1 gpvtg ontime 1.0 dgpstimeout 30 saveconfig The effect of Line 1 is to disable any outputting from the GPS unit. Line 2 will enable the receiving of RTCM corrections on the serial receive line of the second port and enable NMEA outputting on the transmit line. If no reference station is to be set-up this line can be omitted. Lines 3 and 4 will send the GGA, GSA and VTG data every second. Line 4 will enable the reset of the differential mode if RTCM corrections are not received for a period of 30 seconds. Line 5 will save the configuration in the flash memory of the GPS receiver and the configuration will be re-used at power up. By opening the ASCII messages window (View) and entering the command Log gpgga ontime 1.0 The receiver will also return the GGA data to com1 and the data will be displayed as shown below.

GPS Page 6.7.8



Reference Station Setup: The set of the Novatel as a reference station will apply if the GPS unit is placed in the SPII which will be used as an encoder. The true position of the recording truck will have to be entered in this procedure. A typical set-up for the reference station is shown below:

Unlogall Interfacemode com1 none rtcm off

Fix position 51.11358042 –114.04358013 1059.4105 Log com1 rtcm1 ontime 5 Saveconfig The above values correspond to a location in Alberta, Canada. Note that the fix position should reflect the position of the of the antenna of the reference station using:

Lat, Long, Hgt Where Lat is the latitude from –90 to 90 degrees, negative numbers are southern hemisphere. The format is DD.dddd (degrees with 4 decimal places of degrees)

Long is the longitude from –360 to 360 degrees. Negative numbers indicate displacement from zero degrees longitude in a westward direction. Positive numbers indicate displacement from zero degrees longitude in an eastward direction, e.g. -90 and +270 both indicate 90 degrees west longitude. The format is DD.dddd. The 4th decimal place in degrees longitude or latitude at the Equator is roughly 10 cm distance. Hgt is the altitude from –1000 to 20000000 (Mean Sea Level). The resolution for height is meters.

GPS Page 6.7.9



Novatel troubleshooting tips If the commands appear to be unsuccessful but the communication has shown to be operating satisfactorily a command “FRESET” will return the unit to the factory default and clear the RAM of the GPS unit. This will lead to a need to rebuild the almanac before the GPS will output any data. The NMEA message will show the type of message i.e. $GPGGA followed by empty fields and the sum check of the line. After completion of the almanac reload, which takes approx. 12 minutes, the normal data will be returned in the messages. THE RECEIVER MUST BE CONNECTED TO AN ANTENNA AND RECEIVING SIGNALS FROM SATELLITES DURING THE FRESET PROCEDURE. THE RECEIVER WILL NOT OPERATE NORMALLY UNTIL AT LEAST 12 MINUTES AFTER FRESET. If the rovers are not going into differential mode as expected, one may:

1. Go to the reference station 2. Start the Novatel program, gpsolution4.exe, and connect to the

receiver 3. Open the Position Window from the View menu 4. If all is working well, the Solution Status should be “Computed”

and the Position Type should be “Fixed”.

5. The data in the Position Window for a rover should say “Position Type: Single” if not in differential mode. It should say “Position Type: PSR Diff” if in the differential mode.

One may also look at the Tracking Status window to see if enough satellites are being received. A minimum of 3 or 4 satellites will be required for good RTCM data. The color of the text for each satellite indicated the status of the signal from that satellite. Green indicates satisfactory signal and tracking time. If no satellites are found there may be a problem with the card, antenna, or antenna cable. Another helpful indication is the Port Status log. One may:

1. Open the Console Window 2. In the command window, enter log portstats ontime 5

(The last character indicates how often the report will be sent from the GPS card. One might set it to the same value as the output of the reference station data.)

3. Every 5 seconds (or whatever on time is set to) a new set of data should appear in the window.

GPS Page 6.7.10



4. Look at the data for Com 1, which should be set up for transmitting RTCM data.

5. That data line should say something like:

Com 1 0 123456 0 0 840 0 0 0 0 6. Each data field is separated from the next by a space. The NovAtel

manual describes all the fields, but we will only be interested in the second field, the one with 123456 in it in this example. That field shows how many bytes of data have been sent from the card. That field may have from 1 to 6 characters in it. If the value in that field is not changing from one set of data to the next, or is only changing a small amount, such as less than 10, the receiver is probably not outputting usable correction data. If the value of that field is changing more than 10 bytes from one report to the next, it is probably outputting usable correction data. Rovers have gone into differential mode when the value was changing by 16 (sixteen) bytes from one report to the next. A change of 100 or more would not be unusual.

Remember, the quickest way to resolve a problem may be to “FRESET” all the units, reference station and rovers, and resetting them according to the procedures listed earlier in this document.

SPII Encoder Entry Page 7.1.1



SHOT PRO II ENCODER ENTRIES POWER To turn the SPII unit "ON", press and hold the arm button for approximately 3 seconds. MAIN MENU (ENCODER MODE) Lights blink green every second. The main menu will display current status. The display shows battery voltage and operation mode, (either decoder or encoder mode). The cursor up and down keys adjust the display for optimum readability in the main menu.

ENCODER MODE

A FIRE

C DATA ENTRY

D SHOT HISTORY

E RADIO MODE


A. FIRE - Select to setup to Fire shot. Page 7.1.2 C. DATA ENTRY - Select to enter Data Entry Menu. Page 7.1.3 D. SHOT HIST - Select to review or retransmit data from previous shots.

Page 7.1.11 E. RADIO MODE - Select to enable Radio Reception of the re-transmitted

PFS. Clr. OFF - Select to turn SPII unit off. Push button 3 times. Contrast Adjustment - Use the up and down arrows keys in main menu to adjust contrast of display. This adjustment is required when using the SPII at temperature extremes.




A. FIRE MENU Press "A" to enter Fire Menu. Displays the following information. Lights will flash red every second.

ENCODER MODE

A FIRE



Set Crew # and Start Code # to match Decoder unit to be controlled. Entering CREW #15 and DECODER #15 enables all SPII Units on the selected start code. Use the up and down arrow keys to move the highlight bar, use keypad to change the number, pressing "Ent" after selection will enter number and advance to next selectable entry line. Remote Fire must equal "On" for the Recording System to start the SPII Unit. The Remote Fire and Auto Arm modes must be changed in the Data Entry menu under the Hardware setup menu. Press "A" to Enable the local fire screen. Lights will flash rapidly red. The following information will be displayed.

ENCODER MODE

MANUAL FIRE ^



Pressing the up arrow "^" will Manually send start codes to Decoders. After the Fire command is pressed the left green light will stay green until done transmitting.




C. DATA ENTRY MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar to the different selections. When in any menu, pressing "B" will return you to the main menu.

DATA ENTRY MENU

1. JOB PROFILE 2. RADIO CONTROL 3. REPORT 4. HARDWARE SETUP 5. STATUS B RETURN

The following menus are described in more detail on the following pages. Job Profile = Page 7.1.4 Radio Control = Page 7.1.6 Report = Page 7.1.8 Hardware Setup = Page 7.1.9 Status = Page 7.1.10 Return = When ever in a sub-menu, pressing "B" will return you to the

main menu. Press "B" to return to main menu.




JOB PROFILE MENU Lights will flash green every 1 sec. Use the up and down arrow keys to move the highlight bar to the different selections. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the "Ent" key to accept the selection. When in any menu, pressing "B" will return you to the main menu.

JOB PROFILE

1. BOX # = 10 2. CREW # = 15 3. BOX MODE = ENC 4. MSTR/SLV = OFF 5. REC SEQ = OFF 6. PASSWORD = OFF C DATA ENTRY

B RETURN

1. BOX # = Lets the user enter in the ID # of the shooting box, Box ID#’s

0-15 are valid. Box ID# must match Shot Pro # selected from Encoder for shot to fire. If the Encoder selects Shot Pro #15 all units will fire if crew ID # is satisfied. If in Vib Pro mode, Box ID # 1-15 are valid.

2. CREW # = Is an entry to identify a crew. This entry allows multiple

crews to work in the same area without the worry of one crew firing another crews boxes. 0-99 is the range of entries. Crew ID # must match Crew ID # selected from the Encoder for shot to fire. If the Encoder selects CREW #15 all units fire if BOX # entry is satisfied.

3. BOX MODE = ENC – Changes the SPII to Encoder mode.

DEC – Changes the SPII to Decoder mode.

4. MSTR/SLV = OFF – Normal Encoder Mode

MASTER - Master Encoder Mode - In Master Mode, the Encoder sends master codes that contain Crew ID # and Box ID # to the Slave Encoder.

SLAVE – Slave Encoder Mode




5. REC SEQ = Recorder Command Sequence

On – with RTI OFF – without RTI If the REC SEQ is ON, the SPII is able to receive the Sequence code message ID =0002 This message contains the information for the next shot. Message format: Bytes 1 & 2 ASCII "IO" or "RS" Bytes 3 & 4 Number of bytes to follow Bytes 5 & 6 Identification number of the message Bytes 7 & 8 Revision level of the message Byte 9 Sequence Number (Decoder ID # to fire) Byte 10 Serial Number identifier attached by the Recording system Byte 11 Checksum XOR of ID, Revision, Seq Nbr and

Serial Nbr

Example of message ID = 0002 Version = 1 52 53 00 07 00 02 00 01 0A 19 10 52 = ASCII for "R" 53 = ASCII for "S" 0007 = Size is 7 bytes 0002 = ID is 0002 0001 = Version 1 0A = Sequence Number is 0A (Decoder ID # 10 will fire) 10 = Checksum is 10

System 2000: If not working in SDA the RTI connection must be there.

6. PASSWORD = Password Mode is usually set to off, but can be enabled.

- To enable or change the password, use the up/down arrow keys to move the highlighting bar to line 6. Use the left/right keys to select password = ON and follow the instructions on the screen. The access code is 1907. Press "F" to confirm the password.

- To disable the password use the up/down arrow keys to move the highlighting bar to line 6. Use the left/right arrow keys to select PASSWORD=OFF and follow the instructions on the screen.

Note: If the Password is forgotten or corrupted call Pelton Company and ask for help to correct the problem. Phone numbers are located in front of this manual.

If the password is enabled: At power up enter password as prompted Or Supervisory password (confidential) Then password can be turned off or modified

Press "B" to return to main menu.




RADIO CONTROL MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar to the different selections. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the "Ent" key to accept the selection. Pressing "B" will return you to the main menu.

RADIO CONTROL

1. START CODE = 1 2. START Dly = 560uS 3. ENCODER Dly =1000mS 4. Rad Ref Dly = 800uS 5. READY TONE = MSG 6. PFS DATA = ON 7. MICPolarity = NORM 8. SPKRPolarity = REV

C DATA ENTRY

B RETURN

1. START CODE = Start codes 0, 1 and 2 are valid. This entry must match the start code entered in the Decoder for the shot to fire.

2. START DLY = Allowable entry is 0 to 2600 uSec. This entry is used to compensate for the one-way radio delay from the Encoder to the Decoder. This value should be adjusted to align the Fire pulse from the Decoder with the Clocked Time Break (CTB) of the Encoder.

3. ENCODER DLY = A entry between 1000mSec to 9999 mSec. This entry is used to set the time between the Start of Fire Sequence and the Time Break. An entry of 1000 mSec is the normal entry.

4. RAD REF DLY = 1uSec – 9999uSec - The Radio Ref Delay in the Encoder is

used to align the timing marks on the Time Break/Timing Mark output line with the following signals on the Analog data line. • Decoded Clock Time Break (1.0 sec) • Confirmation Time Break (1.5 sec) • Uphole Signal (2.0 sec.) After setting up the START DLY, adjust the Radio Ref Delay to align the Timing Mark at 1 second with the Decoded Clock Time Break Signal.




5. READY TONE = OFF, Tone, MSG

OFF – Nothing radio transmitted when Decoder is charged.

Tone – A 322Hz Ready Tone is radio transmitted when the Decoder is charged.

MSG – The default or last GPS position taken is radio transmitted when the Decoder is charged. The Box ID # will be displayed when the Encoder is in the Fire Menu. The GPS position will be sent to the computer. Default – Ready Message.

6. PFS DATA = ON – Sends PFS data after the Decoder fires in Slave

Encoder mode. OFF – Does not send PFS data after the Decoder fires.

7. MIC POLARITY = NORM/REV - The radio microphone polarity can be changed

without having to physically swap microphone active and return wiring to the Shot Pro.

Note: The wiring and this entry must be the same between boxes or the timing between SPII’s will not be the same.

8. SPKR POLARITY = NORM/REV – This entry allows changing of the Radio

Speaker polarity without having to physically swap the speaker wires to the SPII.

Note: The wiring and the entry must be the same or else the timing may not be the same from box to box.





REPORT MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the "Ent" key to accept the selection. Pressing "B" will return you to the main menu.

REPORT

1. MEMORY LOAD = ON 2. SHOT COUNT = 177 3. NORMALIZE = ON

C DATA ENTRY

B RETURN

1. MEMORY LOAD = ON - Radio reception is allowed at all times by both the

Decoder and Encoder.

OFF - Radio reception by the SPII is only allowed right after the shot in the Encoder and when the box is waiting for radio fire in the Decoder. Radio reception in the Encoder is also allowed when in the Radio Mode Menu and in the GPS Acquisition Mode or Navigation mode in the Decoder.

2. SHOT COUNT = Displays current shot count number 1 through 500. Enter

different number to reset count or erase previous shot. Enter 001 to restart log.

3. NORMALIZE = ON - When set to "ON", the Y-axis of the display of uphole

signal is set to match the maximum of the signal.

OFF - When set to "OFF", the display is set to full scale of A/D converter. Normally set to "ON".





HARDWARE SETUP MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the "Ent" key to accept the selection. Pressing "B" will return you to the main menu.

HARDWARE SETUP

1. AUTO ARM = ON 2. UH Disp TIME = 30 S 3. REMOTE FIRE = OFF 4. DEFAULT PAR = OFF 5. AIRGUN MODE = OFF 6. PRE START = 50uS 7. GPS Ref Stat = Int 8. GPS Corr TX = IntMdm

C DATA ENTRY

B RETURN

1. AUTO ARM = On - The SPII Encoder will automatically re-arm after a

firing sequence if the Auto Arm is turned "On". In this mode of operation, the SPII Encoder will accept a start command from the recording system any time after the Fire Mode is initially entered.

Off – The automatic re-arm is turned off.

2. UH DISP TIME = This entry selects the amount of time the uphole signal is displayed in the Encoder after a shot. The range is 01 to 99 seconds with 00 being “OFF”.

3. REMOTE FIRE = ON – Enables the Remote Fire input.

OFF – Turns off the Remote Fire input.

4. DEFAULT PAR = OFF – Is the normal default,

LOAD - Allows default keyboard parameters to be loaded into the SPII. Both Encoder and Decoder keyboard parameters will be set to the default keyboard parameters. Setting in the default parameters is a two-step process. Press the left arrow key to select "load" option then press the "Ent" button. On the next screen press the "D" to go to Load the default parameters.

5. AIRGUN MODE = This option is not currently available in initial release of the SPII Unit. Default is set to Off.

6. PRE-START = Adjustable pulse on Analog Data line. Pulse adjusts from

starting at 1mSec to 145mSec before Time Break. Pulse is used to start Air Gun.




7. GPS REF STAT = INT – Internal GPS usable as reference station. SET – Allows to set up the Internal GPS. EXT – External GPS usable as reference station. SET – Allows to set up the External GPS

8. GPS CORR TX = IntMdm – Internal Modem usable to send RTCM correction. ExtMdm – External Modem usable to send RTCM correction.

STATUS MENU Lights will flash green every second. No changeable entries are available, the status screen is to show what software and the firmware checksum that are loaded in the SPII unit. Pressing "B" will return you to the main menu.

STATUS

1. SOFTWARE Ver = 1.004 2. CHECK SUM = 40C8

C DATA ENTRY

B RETURN

1. SOFTWARE VER = Current Software Version installed in the unit. 2. CHECKSUM = 40C8 – This number is a example, it provides information on

the Firmware installed in the unit.




SHOT HISTORY MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the keypad to enter numerical values followed by the "Ent" key to accept the selection. Pressing "B" will return you to the main menu.

SHOT HISTORY MENU LAST SHOT#= 46

1. DISPLAY SHOT# = 46 Press D to Display

RE-TRANSMIT ENTRY 2. START# = 46 3. END# = 46 Press F to transmit

B RETURN

1. DISPLAY SHOTS = Displays previous shot history. Using the keypad the

shot number can be entered followed by the "Ent" key. Press "D" to display the shot. That shot number will be displayed as follows:

Sh#=46 Flg#=12345678 V 1st PICK=40.00mS

3.8 1.9

10 20 30 40 50 mS -1.9 -3.8

B RET CTB=0.005mS

Press "B" to Return to the Shot History Menu. RE-TRANSMIT ENTRY

Allows previous shot(s) to be retransmitted. 2. START# = Enter the Starting shot number to retransmit. (1-500) 3. END# = Enter the ending shot number to retransmit. (1-500) To retransmit shot(s) press the "F" key. Following page shows screen.




RE-TRANSMIT MENU

TRANSMIT SHOT # 46

B RETURN

The shots will be retransmitted over radio and computer serial port then the screen will come back to the Shot History Menu. If for any reason you need to cancel the retransmit process, use the "B" key to cancel the function. The Decoder also sends the data directly to the computer by the computer serial port.

mgray

Page 7.1.13

Decoder Entry Page 8.1.1



SHOT PRO II DECODER ENTRIES POWER To turn the SPII unit "ON", press and hold down the arm button for approximately 3 seconds. MAIN MENU (DECODER MODE) Lights blink green every second. The main menu will display current mode status, (either decoder or encoder mode) and shows battery voltage. The cursor up and down keys adjust the display for optimum readability in the main menu.

DECODER MODE

A ARM

C DATA ENTRY

D SHOT HISTORY

E GPS

F TEST OFF Clr BATTERY = 12.25Volt

A. ARM - Select to setup to Fire shot. Page 8.1.2 C. DATA ENTRY - Select to enter Data Entry Menu. Page 8.1.4 D. SHOT HISTORY - Select to review or retransmit data from previous

shots. Page 8.1.12 E. GPS – Select to acquire GPS position from the internal GPS receiver.

Page 8.1.14 F. TEST – Select to test resistance of uphole and cap lines. Page 8.1.17 Clr. OFF - Select to turn SPII unit off. Push button 3 times. Contrast Adjustment - Use the up and down arrows keys in main menu to adjust contrast of display. This adjustment is required when using the SPII at temperature extremes.




A. ARM MENU - Press the "A" button to enter Arm Menu. When in the Arm Menu the two Lights will blink Red every second. The Arm menu shows the current geophone noise level, the data from the Cap line test, Uphole phone test, GPS position, and the entered flag #. The screen will look similar to the following:

**WARNING** ARMING CAP! PRESS CHARGE BUTTON TO CHARGE CAP Lat = 29 34.5666N Long =081 36.0500W FLAG# 456 CAP = .3 Ohms UPHOLE = 977 Ohms NOISE = .000020VOLT B RETURN

The noise level of the uphole geophone can be monitored in this menu. The noise level displayed is the uphole phone's peak voltage. This display is updated every one second. The Exploration Co. or Client should determine the maximum allowable uphole phone voltage. CHARGE MENU - Press “B” to return to Main Menu or press “Charge” to charge cap. The lights will both flash red at first till the cap is full. Right light will stay on when the cap is fully charged and left light will flash red until ARM is pushed. The charge menu looks similar to the following:

**WARNING**

CAP IS CHARGING NOISE = .000020VOLT B RETURN

**WARNING** CAP FULL NOISE = .000035VOLT

B RETURN




Note: When the battery is discharged down to an approximate 10.5 V, the left LED turns to a flashing green-red to indicate a marginal operation. If the battery voltage goes below 10 Volts the attempt to charge the cap will be denied and a message displayed to that effect. Only the left LED will be flashing red. When the cap is fully charged, while continuing to press the charge button press the Arm button to fire the shot. If the ready tone is enabled, it will automatically be sent to the recording truck at this time. The following menu will appear when the ARM and Charge buttons are both pressed.

DANGER!

SYSTEM IS CHARGED DANGER! WAITING FOR RADIO FIRE COMMAND

NOISE = .000035VOLT B RETURN

When the Fire command is received from the encoder and the SPII has fired the cap, the left light will change to green when transmitting data back to the encoder and right light will change to green when firing process is complete. Press “B” to return to the Main Menu.




C: DATA ENTRY MENU LED lights will flash green every second. Pressing “B” will return you to the Main Menu.

DATA ENTRY MENU

1. JOB PROFILE 2. RADIO CONTROL 3. REPORT 4. TEST LIMITS 5. UH CHANNEL SETUP 6. HARDWARE SETUP 7. STATUS B RETURN

The following menus are described in more detail on the following pages. 1. JOB PROFILE = Page 8.1.5 2. RADIO CONTROL = Page 8.1.6 3. REPORT = Page 8.1.7 4. TEST LIMITS = Page 8.1.8 5. UH CHANNEL SETUP = Page 8.1.9 6. HARDWARE SETUP = Page 8.1.10 7. STATUS = Page 8.1.11 Press “B” to return to main menu.




JOB PROFILE MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the “Ent” key to accept the selection. Pressing “B” will return you to the main menu.

JOB PROFILE

1. FLAG# = 456 2. BOX # = 10 3. CREW # = 15 4. BOX MODE = ENC 5. COMM MODE=SHOTPRO 6. PASSWORD = OFF

C DATA ENTRY

B RETURN

1. FLAG # = Can be entered from this menu or will be entered automatically if navigating to a selected flag.

2. BOX ID# = Must be entered here. These selections are required so that the box can be identified by the encoder. Enter in the ID # of the shooting box, Box ID# 0-15 are valid. Box ID# must match Shot Pro # selected from Encoder for shot to fire. If the Encoder selects Shot Pro #15 all units will fire if crew ID # is satisfied. If in Vib Pro mode, Box ID # 1-15 are valid.

3. CREW ID # = Must be entered here. These selections are required so that the box can be identified by the encoder. Enter to identify a crew. This entry allows multiple crews to work in the same area without the worry of one crew firing another crews boxes. 0-99 is the crew # range of entries. Crew ID # must match Crew ID # selected from the Encoder for shot to fire.

4. BOX MODE = ENC – Changes the SPII to Encoder mode. DEC – Changes the SPII to Decoder mode.

5. MODE = ADV II - the Decoder operates with Advance II start codes and sends Original Advance II PFS data back. The Decoder will send the Ready tone or the ADVII ready message (if selected) when ready to fire.

VIB PRO - The Decoder can receive Vib Pro start codes and transmit PFS in the Vib Pro format. The Decoder will also send the Vib Pro ready message (if selected) when ready to fire.

SHOT PRO - The Decoder will receive Advance II Start Codes and transmit PFS in the Vib Pro Format. The Decoder will also send the Vib Pro ready message (if selected) when ready to fire.

6. PASSWORD = See Encoder Password.

Press “B” to return to main menu.




RADIO CONTROL MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar to the different selections. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the “Ent” key to accept the selection. Pressing “B” will return you to the main menu.

RADIO CONTROL

1. START CODE = 1 2. DECODER Dly = 0uS 3. BAUD RATE = HIGH 4. READY TONE = MSG 5. PFS DATA = ON 6. MICPolarity =NORM 7. SPKRPolarity = REV

C DATA ENTRY

B RETURN

1. START CODE = Start codes 0, 1 and 2 are valid. This entry must match the start code entered in the encoder for the shot to fire.

2. DECODER DELAY = Allows the firing of the Decoder to be delayed by the amount of this entry. Range is 0 uSec to 9999 uSec. 0uSec is the typical entry for the Decoder delay.

3. BAUD RATE = Selects High or Low baud rate when data is retransmitted to Encoder. Set to High in Shot Pro mode.

4. READY TONE = OFF – Nothing radio transmitted when Decoder is charged.

Tone – A 322Hz Ready Tone is radio transmitted when the Decoder is charged.

MSG – The default or last GPS position taken is radio transmitted when the Decoder is charged. The Box ID # will be displayed when the Encoder is in the Fire Menu. The GPS position will be sent to the computer. Default – Ready Message.

5. PFS DATA = ON – Sends PFS data after the Decoder fires. OFF – Does not send PFS data after the Decoder fires.

Selected if in slave mode.

6. MIC POLARITY = NORM/REV - The radio microphone polarity can be changed without having to physically swap microphone active and return wiring to the Shot Pro. Typically Norm

Note: The wiring and this entry must be the same between boxes or the timing between SPII’s will not be the same.




7. SPKR POLARITY = NORM/REV – This entry allows changing of the Radio Speaker polarity without having to physically swap the speaker wires to the SPII.

Note: The wiring and the entry must be the same or else the timing may not be the same from box to box.

Press “B” to return to main menu.

REPORT MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the “Ent” key to accept the selection. Pressing “B” will return you to the main menu.

REPORT

1. MEMORY LOAD = ON 2. SHOT COUNT = 177 3. NORMALIZE = ON

C DATA ENTRY

B RETURN

1. MEMORY LOAD = OFF – Radio reception by the Decoder is only allowed when the Box is waiting for radio fire and when in the GPS and Navigation Menu ON – Radio reception is allowed at all times by the Decoder. Typically “On”.

2. SHOT COUNT = Displays current shot count number. Enter different

number to reset count or erase previous shot. Enter "0" to restart log from start. After shot 500 will start over at 1.

3. NORMALIZE = ON - When set to "ON", the Y-axis of the display of the

uphole signal is set to match the maximum of the signal. Adjust uphole to full screen resolution.

OFF - The display is set to full scale of A/D converter. Normally set to "ON". If OFF scale = 4 V @ 0dB 400 mV @ 20dB 40 mV @ 40dB




TEST LIMITS MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the keypad to enter numerical values followed by the “Ent” key to accept the selection. Pressing “B” will return you to the main menu.

TEST LIMITS

FIRE LINE

UPPER LIMIT =1200 OHMS LOWER LIMIT = 0 OHMS GEOPHONE UPPER LIMIT =1200 OHMS LOWER LIMIT = 0 OHMS C DATA ENTRY

B RETURN

FIRE LINE

Upper Limit = Sets the Upper Resistance Limit on the Fire Line. Allows a entry of 0 to 1200 Ohms

Lower Limit = Sets the Lower Resistance Limit on the Fire Line.

Allows a entry of 0 to 1200 Ohms GEOPHONE

Upper Limit = Sets the Upper Resistance Limit on the Geophone. Allows a entry of 0 to 1200 Ohms

Lower Limit = Sets the Upper Resistance Limit on the Geophone.

Allows a entry of 0 to 1200 Ohms Note: If measurement is off limits the TEST display (main menu or arm menu) will show Out of Range.




UH CHANNEL SETUP MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the left and right arrow keys to toggle through the menu selections. Pressing “C” will return you to the Data Entry Menu, pressing “B” will return you to the main menu.

UH CHANNEL SETUP

1. UPHOLE GAIN = 00dB 2. BLANK TIME = 5mS 3. SAMPLE RATE = .50mS 4. PICK METHOD = #1

C DATA ENTRY

B RETURN

1. UPHOLE GAIN = Select uphole pre-amp gain of 0db, 20db, or 40db by using the left/right arrow key. Default is 20 dB. Typically set at 0dB to avoid clipping.

2. BLANK TIME = Use the arrow keys to toggle thru the selections. This is the time to blank in mSeconds the uphole phone after shot is fired. 5mS/ 10mS/ 15mS/ 20mS/ 25mS/ 30mS/ 35mS/ 40mS/ 45mS/ Wndw

Wdw setting is currently causing some problems in VibraSig. Wdw will automatically adjust the start (H scale may start at any non-zero time) of the Uphole data window as to optimize the data acquisition. Convenient for delayed uphole signal arrival. Typical set to 5mS.

3. Sample rate = .50mS typical. .25mS may be misleading for QC software and system.

4. PICK METHOD = Various pick methods for determining uphole time can be selected by using the left/right arrow key. The first 4 selections (1-4) automatically find the beginning of the lobe. Typically set to 1

In all pick methods a threshold voltage is determined. When this threshold Voltage is reached 3 consecutive times, then the pick time is determined. Most of the methods are determined from the background noise 250msec before the shot.

1 - Threshold = Peak noise x 2 Automatic beginning of lobe.

2 - Threshold = Average noise x 2 Automatic beginning of lobe.

3 - Threshold = Computed from acquired data using peak noise level.

Automatic beginning of lobe. 4 - Threshold = Computed from acquired data using

average noise level. Automatic beginning of lobe.




HARDWARE SETUP MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the left and right arrow keys to toggle through the menu selections or the keypad to enter numerical values followed by the “Ent” key to accept the selection. Pressing “B” will return you to the main menu.

HARDWARE SETUP

1. AUTO OFF = OFF 2. UH Disp TIME = 30 S 3. REMOTE FIRE = OFF 4. DEFAULT Par = OFF 5. AIRGUN MODE = OFF 6. PRE START = 50mS 7. GPS MODE = IntGPS 8. GPS Corr RX = IntMdm

C DATA ENTRY

B RETURN

1. AUTO OFF = Let’s the user enter automatic shut down time, enter 0-99

minutes. Enter 0 to disable Auto off. Typically set to Off. 2. UH DISP TIME = This entry selects the amount of time the uphole signal

is displayed in the Encoder after a shot on the display before returning to the main menu. The range is 01 to 99 seconds with 00 being “OFF”. Typical 5Sec.

3. REMOTE FIRE = ON - The Decoder can be fired by the Remote Fire input.

The shooter is required to hold the “ARM” and “CHARGE” switches when the Remote Fire signal is issued.

OFF – Turns off the Remote Fire option. Typically set to Off.

4. DEFAULT PAR = OFF – Is the normal default,

LOAD - Allows default keyboard parameters to be loaded into the SPII. Both Encoder and Decoder keyboard parameters will be set to the default keyboard parameters. Setting in the default parameters is a two-step process. Press the left arrow key to select “load” option then press the “Ent” button. On the next screen press the “D” to go to Load the default parameters. This will return the SPII to Encoder mode.

5. AIRGUN MODE = Default is set to Off. 6. PRE-START = Adjustable pulse on Analog Data line. Pulse adjusts from

starting at 1mSec to 145 mSec before Time Break. Pulse is used to start Air Gun.




7. GPS MODE = INT – Internal GPS. SET – Allows to set up the Internal GPS. EXT – External GPS. SET – Allows to set up the External GPS

8. GPS CORR TX = IntMdm – Internal Modem for RTCM correction. ExtMdm – External Modem for RTCM correction. STATUS MENU Lights will flash green every second. No changeable entries are available, the status screen is to show what software and firmware checksum that are loaded in the SPII unit. Pressing “B” will return you to the main menu.

STATUS

1. SOFTWARE Ver = 1.004 2. CHECK SUM = 40C8

C DATA ENTRY

B RETURN

1. SOFTWARE VER = Current Software Version installed in the unit. 2. CHECKSUM = 40C8 – This number is an example, it provides information

on the Firmware installed in the unit.




SHOT HISTORY MENU Lights will flash green every second. Use the up and down arrow keys to move the highlight bar. When on selection use the keypad to enter numerical values followed by the “Ent” key to accept the selection. Pressing “B” will return you to the main menu.

SHOT HISTORY MENU LAST SHOT#= 46

1. DISPLAY SHOT# = 46 Press D to Display

RE-TRANSMIT ENTRY 2. START# = 46 3. END# = 46 Press F to transmit

B RETURN

1. DISPLAY SHOTS = Displays previous shot history. Using the keypad the

shot number (1-500) can be entered followed by the “Ent” key. Press D to display the shot. That shot number will be displayed as follows:

Sh#=46 Flg#=12345678 V 1st PICK=40.00mS

3.8 1.9

10 20 30 40 50 mS -1.9 -3.8

B RET CTB=0.005mS

Press “B” to Return to the Shot History Menu. RE-TRANSMIT ENTRY

Allows previous shot(s) to be retransmitted. 2. START# = Enter the Starting shot number to retransmit. (1-500) 3. END# = Enter the ending shot number to retransmit. (1-500) To retransmit shot(s) press the “F” key. Following page shows screen.




RE-TRANSMIT MENU

TRANSMIT SHOT # 46

B RETURN

The shots will be retransmitted then the screen will come back to the Shot History Menu. If for any reason you need to cancel the retransmit process, use the “B” key to cancel the function. The Decoder also sends the data directly to the computer serial port.




GPS MENU Lights will flash green every second. The GPS Menu will come up with no data until the right arrow is pressed to start acquiring GPS data. Pressing “D” will take you to the Flags Menu, pressing “E” will to go to the Navigation Menu. Pressing “B” will return you to the main menu.

GPS MENU

AVERAGING MODE = 0 START <

D FLAGS

E NAVIGATE

B RETURN

Press the right arrow key (<) to start acquiring GPS.

GPS MENU

AVERAGING MODE = 0 LAT = 34 44.4625N LONG = 095 46.0955W P=0.0 H=0.0 V=0.0

D FLAGS STOP >

E NAVIGATE

B RETURN

Once a position that decided to stop acquiring GPS data push the right arrow key (>). While in this menu other selection are not available until the key is pressed to stop acquiring GPS data. The screen will look like the one on the following page. Averaging mode selection: 0 – Last Position 1 – Middle (best) position 2 – Average position Press 0, 1 or 2 and the “Ent” to select the averaging mode.




GPS MENU

AVERAGING MODE = 0 LAT = 34 44.4625N LONG = 095 46.0955W LAST POSITION

START <

D FLAGS

E NAVIGATE

B RETURN

The screen shows the last GPS position received. Stop to store the shot point position. FLAGS MENU Lights will flash green every second. Pressing “E” will to go to the GPS Menu. Pressing “B” will return you to the main menu.

SP1 FLAGS MENU

FLAG# 29921205 FLAG# 29921206 FLAG# 29921207 FLAG# 29921208 FOUND FLAG#

E GPS SAVED 499

B RETURN

In the SP1 Flags menu, use the up and down arrow keys to move the highlight bar on the selection. When the bar gets to the top or the bottom of the screen, pressing the arrow keys will bring the next flag number in sequence. Or the keypad can be used to enter the numerical flag values followed by the “Ent” key to accept the selection.




NAVIGATION MENU In the Navigation Menu the LEDs will show the direction to the selected flag.

NAVIGATION MENU

NAV TO FLG# 29921206 AZIMUTH = 30 deg DISTANCE = 20 m SPEED = 5 k/H E GPS

NAV TO FLG# = The Flag # is the flag that you are navigating to, go to the Flags menu to select flag from menu or enter flag number by using the keyboard. The flag selected in that menu is the flag the unit will navigate to. DISTANCE = The distance to the flag in meters. SPEED = The speed in which the unit is traveling




TEST MENU Press the "F" key from the Main Menu to enter the test menu. The following menu will appear for a about 3 seconds.

CALIBRATION

IN PROCESS!!

BE SURE *ARM* BUTTON

RELEASED

B RETURN

After the Calibration is complete the following menu will then be shown:

TEST MENU

PRESS *ARM* BUTTON For FIRING LINE test * CHARGE* BUTTON For GEOPHONE test E PULSE TEST

C CALIBRATION

B RETURN

FIRING LINE TEST:

• Hold the Arm button down. • Continue to hold the arm button down until the display updates.

FIRING LINE RESISTANCE

UPPER LIMIT = 5 OHMS LOWER LIMIT = 2 OHMS FIRE LINE = 2.6 OHMS

F TEST

B RETURN

Press “F” to return to the Test Menu or “B” to return to Main menu.




GEOPHONE TEST • Hold the Charge button down. • Continue to hold the Charge button down until the display

updates.

GEOPHONE RESISTANCE

UPPER LIMIT = 350 OHMS LOWER LIMIT = 275 OHMS GEOPHONE = 300 OHMS

F TEST

B RETURN

Press “F” to return to the Test Menu or “B” to return to Main menu. To perform a pulse test press the “E” key in the Test Menu.

PULSE TEST V

.38 .19

0 30 60 90 120 mS -.19 -.38

B RET TEST F

Press “F” to return to the Test Menu or “B” to return to Main menu. Calibration Menu The calibration menu is the same menu that comes up when entering the Test Menu. Pressing “C” will recalibrate the SPII unit.

Decoder Page 9.1.1



SHOT PRO II DECODER OPERATION

1) Press and hold "ARM" button to turn unit on.

DECODER MODE

A ARM

C DATA ENTRY

D SHOT HISTORY

E GPS

F TEST OFF Clr BATTERY = 12.25Volt

2) Acquire GPS position with GPS menu.

GPS MENU

AVERAGING MODE = 0

LAT = 34 44.4625N LONG = 095 46.0955W LAST POSTION

START <

D FLAGS

E NAVIGATE

B RETURN

3) Enter Flag number in the Flags menu. Enter the Flag number in Job

Profile if the SP1 flags have not been loaded.

SP1 FLAGS MENU

FLAG# 29921205 FLAG# 29921206 FLAG# 29921207 FLAG# 29921208 FOUND FLAG#

E GPS SAVED 499

B RETURN

Decoder Page 9.1.2



4) Connect the uphole geophone and cap firing line. Use the test menu selection to test geophone and cap resistance. Before testing cap resistance clear the area and follow proper safety procedures.

TEST MENU

PRESS

*ARM* BUTTON For FIRING LINE test

* CHARGE* BUTTON For GEOPHONE test E PULSE TEST

C CALIBRATION

B RETURN

5) When ready to fire cap, first clear the area and follow all safety

procedures. Keep hands and fingers clear of high voltage connections.

• Press the ARM (A button) key from the main menu.

• The following data is displayed; Geophone Test results, Cap Test results, GPS position and the current Geophone Noise.

**WARNING** ARMING CAP! PRESS CHARGE BUTTON TO CHARGE CAP Lat = 29 34.5666N Long =081 36.0500W FLAG# 456 CAP = 3.0 Ohms UPHOLE = 312 Ohms NOISE = .000020VOLT B RETURN

Decoder Page 9.1.3



• Press and hold the charge button until high voltage cap is charged.

**WARNING** CAP IS CHARGING NOISE = .000020VOLT B RETURN

**WARNING**

CAP FULL

NOISE = .000035VOLT

B RETURN

• While pressing the charge button also press the ARM button. The unit will now send the ready tone to the Recording System if Ready Tone is Enabled.

• Press and hold both the charge and ARM switch until the cap has been fired.

DANGER!

SYSTEM IS CHARGED

DANGER!

WAITING FOR RADIO FIRE COMMAND

NOISE = .000035VOLT B RETURN

Decoder Page 9.1.4



• After the cap has been fired, the uphole signal is displayed on the screen, and the uphole pick time is shown.

Sh#=36 Flg#=12345678 V 1st PICK=40.00mS

3.8 1.9

10 20 30 40 50 mS -1.9 -3.8

B RET CTB=0.005mS

Installation Page 10.1.1



SHOT PRO II ENCODER INSTALLATION The Shot Pro II Encode Cable Connector JF provides connections for power, radio, and recording system interface. Each wire in the SPII Encode Cable, wired to a mating PF connector, is labeled according to the JF pin it is connected to. 1. Power Input - The unit is powered by the battery voltage (10-36

VDC), or by a power supply capable of producing 10 to 36 VDC at 10 watts.

Pins b (red 20 gauge) is connected to the positive (+) side of the power source through a 7.5amp fast blow fuse.

Pins c (black 20 gauge) is connected to the negative (-) side of the power source through a 7.5amp fast blow fuse.

2. Radio Interface - The SPII Unit must be connected to a suitable

radio transceiver so the Start Code and data can be transmitted to the Decoder and uphole data can be received from the Decoder.

Some requirements of the radio transceiver are:

A. Response time (from activation of PTT at transmitter to

quieting and stabilization of speaker audio at receiver) - less than 125 milliseconds.

B. Audio Band width (3 dB) - at least 300 Hz to 3000 Hz.

C. Signal to Noise Ratio (Voltage measured at speaker, ratio

between 100 percent modulation and 0 percent modulation) - 20 dB.

D. Required speaker voltage at 100 percent modulation - at least 1

volt peak-to-peak.

E. Transmitter audio input for 100 percent modulation - 2 volts peak-to-peak.

F. Mic. disconnect switch when PTT button released.

G. Negative PTT (the radio must transmit when the PTT line is

connected to common.




The MS3106E14S-5S radio connector is wired to SPII connector PF as follows: Connector Wire type Radio Radio Connection PF pin Connector Y Single conductor A Transmitter input

shielded (Mic High) W Red wire of shielded B Speaker Active

twisted pair Z 22 gauge Black C Radio Return a 22 gauge Yellow D Push-to-talk X Black wire of shielded E Speaker Return

twisted pair If the radio transceiver requires less than 2 volts p-p for 100 percent modulation, an attenuation circuit must be installed in series with the transmitter input. Pelton Company has determined interface circuits for many popular radios and will supply this information on request. See Radio Installation and Testing Section later in this chapter. Wire Line Communications - Communications between an Advance II Encode Sweep Generator or SPII Encoder and Decoder(s) may be accomplished by wire rather than by radio. To do this, connect pins A and B of the five pin radio connector together and connect them to one wire in the cable to be used for communication. Connect pins C and E of the five pin radio connector together and connect them to another wire in the communication cable. Wire line communications should be satisfactory over several miles of cable. There are no provisions for voice communications through the SPII’s, but using the paralleling intercom units on the same wire pair should not cause a problem.




3. Shot Pro II Remote Start Command - The SPII Encoder accepts a start command from the Recording System. It responds by sending start codes to the Decoder and issuing a time break signal.

Pin E (red wire of shielded twisted pair) is connected to the positive (+) side of the voltage pulse and:

Pin F (black wire of shielded twisted pair) is connected to the negative (-) or return side of the voltage pulse.

The SPII START input can be opto-isolated or non isolated. If wanting to use the opto-isolated input remove the SPII front panel and set the S2 dip switches as indicated below: Position 1-8 = OFF 2-7 = OFF 3-6 = ON 4-5 = ON

Refer to page 10.1.9

If wanting to use the non-opto-isolated input remove the SPII front panel and set the S2 dip switches as indicated below: Position 1-8 = ON 2-7 = ON 3-6 = OFF 4-5 = OFF


4. Clock Time Break: Time Break (T.B. Act and Rtn) is generated by the SPII Encoder at the instant the shot is fired.

A switch closing pulse of about 4 milliseconds duration is generated by the SPII Encoder.

Pin J (red wire of shielded twisted pair) is connected to the positive (+) side of the Time Break input.

Pin K (black wire of shielded twisted pair) is connected to the negative (-) or return side of the Time Break input.

The SPII Timebreak output can be opto-isolated or non-isolated. If wanting to use the opto-isolated input remove the SPII front panel and set the S3 dip switches as indicated below: Position 1-8 = OFF 2-7 = OFF 3-6 = ON 4-5 = ON





If wanting to use the non-isolated input remove the SPII front panel and set the S3 dip switches as indicated below: Position 1-8 = ON 2-7 = ON 3-6 = OFF 4-5 = OFF


5. Uphole Signal - Timing verification marks along with the uphole signal are available on the Analog Data line. (see page 5.1.2)

If the auxiliary channel accepts a high-level (10v p-p) input:

A. Connect Pin B (black wire of shielded twisted pair) to the

active input of the auxiliary channel.

B. Connect Pin D (red wire of shielded twisted pair) to the return input of the auxiliary channel.

If the auxiliary channel requires a lower level input, an external resistor divider network must be used.

6. Computer Cable - A 9 pin D connector provides signal connections for the optional computer.

Pin 2, receive of computer, is wired to JF-M. Pin 3, transmit of computer, is wired to JF-L. Pin 5, common of computer, is wired to JF-S.

7. GPS cable – A 9 pin “D” connector provides the signal connections for an external GPS base station if used with single radio option for RTCM corrections or for a computer as to set up the internal Novatel GPS receiver(if so equipped)as a Reference Station.

Pin 2 - Receive line for the computer is wired to JF-U Pin 3 – Transmit line of the computer or Base Station is wired to

JF- T. Pin 5 – Common is wired to JF-S

8. RTI cable – A 9 pin “D” connector provides the signal connections

with the recording system.





9. Recorder Start Command - The SPII Encoder sends a start command to the Recording System approximately 52ms after the start codes have been transmitted. The pulse is a minimum of 150ms in duration. The pulse will need amplification to energize an opto-coupled circuit.

Pin G (Green wire, Rec Start) is connected to the base of the amplifying transistor (2N3904). The emitter is connected to ground and the collector connected to the return side of the External start.

10. Reference marks – The reference marks are for timing verification

purpose. They have a duration of 4 mS and occur at 1.0, 1.5 and 2.0 Seconds after timebreak.

Shot Pro II Decoder Installation Power and Radio use same connection as used for the SPII Encoder. Uphole Geophone - Connect positive output of uphole geophone to JF-C, connect negative output of uphole geophone to JF-A. GPS Receiver - The external GPS receiver can be connected to the SPII Decoder. The RS232 output of the GPS receiver should be connected to JF-T on the SPII Unit. The RS232 RTCM differential correction message input of the GPS receiver should be connected to JF-U. Airgun This mode is not currently available for the initial release of the SPII. Navigational System The Navigational System can send a serial message (maximum 110 bytes) to the SPII Decoder after the Fire command is issued. This data will be sent back to the SPII Encoder with Post Fire Service (PFS). The RS232 Navigational System data output should be connected to JF-T on the SPII Unit. The RS232 common connected to JF-S.




Radio Installation and Testing Radio Set-up Connect the SPII's radio output to the user's radio. The SPII's radio circuit is designed for speaker audio output. However the discriminator audio output of the radio can be used instead. The speaker connection normally gives greater range of reception than discriminator output. Speaker Polarity The radio modulation technique used in the SPII system usually works better with one polarity than the other. Use the SPKR POL entry in the Radio Control menu to check both polarities. The SPII's start command signal is transmitted to the Decoder at 1952 baud. The Post Fire Service (PFS) data is transmitted to the Encoder 3123 baud after detonations, but may be sent at either baud rate during retransmissions. The 3123 baud transmission may require a different polarity than the 1952 baud transmission. Make sure all boxes have the speaker wired the same for timing purposes. The SPII must receive at least 75% of the start data to detonate the charge. To determine the best speaker polarity at the Decoder:

• Set up the Encoder and Decoder to fire a test shot. (The ready tone from the Decoder can be used to make an Advance II Encode Sweep Generator send start blasts when the Decoder is armed and ready.)

• Receive a start blast.

• Receive start blasts with different volume settings on the radio and

both speaker polarities to determine which speaker polarity works best over the widest range of volume settings.

To determine the best speaker polarity if a SPII is acting as the Encoder:

• Set up the Encoder and a Decoder to fire a shot.

• Take a test shot and receive PFS data.

• Receive PFS data with different volume settings on the radio and both

speaker polarities to determine which speaker polarity works best over the widest range of volume settings.

• Setting the Decoder to retransmit at low baud rate and having it

retransmit PFS data is sometimes helpful in troubleshooting PFS data reception problems.

Refer to the Encoder Entries and Decoder Entries chapters of this manual for more detailed descriptions of the Radio Status Words.




Disassembly and Repair Most SPII repairs may be accomplished by removing the front panel, and then the PC board. Caution must be taken after opening the unit because the Board may still have high voltage on the high voltage capacitor, C34. Special care must be exercised if the unit is worked on with power applied while it is removed from the enclosure. Potentially lethal electrical charges may be developed in the unit. Access the boards and front panel for repair by removing the screws as necessary. Schematics and other documents providing information to aid in repairing the SPII are included in the Documentation section of this manual. The display, display card and front panel card are not manufactured by Pelton Company Inc., and are not considered field repairable, and no documentation is provided on those circuits. Assembly When reassembling the SPII, apply some Loctite to the threads of screws and nuts to keep them from coming loose while the unit is in use. Improper reassembly can allow screws and nuts to loosen and cause a major failure. A desiccant is installed in the SPII case. It should be replaced periodically. Installation and proper care of the desiccant are important protection against damage from moisture. Be sure the gasket and sealing surfaces are clean when re-assembling the unit to ensure a good seal. Tighten each screw to the suggested torque values below: Display Module: 6 in lbs Firing Line Posts: 18 in lbs Charge and Arm Switch Nuts: 40 in lbs Front Panel Card: 14 in lbs 26 Pin Connector Screws: 14 in lbs Front panel Screws: 16-24 in lbs Shock and Vibration Isolation The SPII has been designed and constructed to be very resistant to shock and vibration. In some situations, the reliability of the SPII unit may be enhanced significantly if it is mounted using shock and vibration isolation techniques and materials. The Back Pack Option is not intended to provide shock and vibration isolation.

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Options Page 11.1.1



Back Pack

The Back Pack provides a lightweight, rugged, and comfortable way to carry the SPII and related equipment. A cover that protects the radio, battery, and wiring is made of Herculite, which is very durable at a wide range of temperatures and is waterproof. The normal color is bright yellow. Replacement packs and straps are readily available from Pelton Company. After an initial adjustment so the pack fits the individual, taking the pack off and on should be easy and quick. The lumbar strap is adjustable to provide comfort for a wide range of body shapes and loads. The waist strap has a quick release buckle with adjustments that do not have to be disturbed when that strap is buckled or released. Optimum comfort, especially for long periods of packing, can be achieved by supporting the load of the pack primarily on the hips, via the lumbar and waist straps, rather than on the shoulders.

Initial Pack Adjustment

1. Support the pack on a table, shelf, or have someone hold it.

2. Assume a position so that the lumbar strap contacts the back at a comfortable point, usually near the top of the pelvic bone.

3. Adjust the waist strap so that it is snug enough to carry the weight of the pack on the hips.

4. Adjust the upper buckles of the shoulder straps so the shoulder strap pads are positioned with their tops near the tops of the shoulders.

Radio Considerations

Power reflected from the antenna back into the radio when it is transmitting can damage the radio and usually greatly reduces the communication range. Some items that affect reflected power significantly are: antenna tuning, integrity and selection of hardware, antenna design, counterpoise (ground plane), proximity of the antenna to other objects.

Back packs do not provide suitable ground planes for radio antennae. The best vertical antenna design for operation without a ground plane is the base loaded, half wave. It gives significantly greater reflected power stability and greatly improved radiational efficiency over any other antenna design that is practical for back packing. Therefore, radio communications can be improved substantially by using a 1/2 wave vertical antenna with almost any radio being used on a pack. When a spring is installed between the base load and the radiating rod, the antenna is flexible enough to be suitable for use even in dense brush and trees. The orientation of any antenna is critical for optimum communication range. Most antennae used for local communications on seismic crews are mounted vertically, giving vertical polarization. If the backpack is used laying down, with the antenna in the horizontal position, the power radiated from the antenna is polarized horizontally. This by itself results in a significant reduction in communication range (about 20 dB).

Options Page 11.1.2



A second disadvantage of operating the antenna horizontally is that the reflected power typically will be much higher, primarily due to the proximity of the antenna to the ground or other objects. This reflected power can damage the radio. It will cause many radios' protection systems to reduce the transmit power significantly. Another disadvantage of this position is the low elevation of the antenna above the ground. Merely raising the antenna from the horizontal to the vertical position provides an increase in antenna elevation that is significant for increasing communication range. Optimum communication range and radio performance can be ensured by positioning the antenna mount so the antenna is nearly vertical when shots are being fired. This may result in the antenna being vertical when the pack is vertical, leaned back at about 45 degrees, or laying flat with the SPII facing up. If the Pelton Antenna mount is used with half-wave vertical antenna, it is critical that the BA (the large all-thread part of the mount that the antenna base load screws on to) be adjusted properly. The BA must extend above the nut on top of the mount 5/16" +0.00" - 1/16" (7.9mm +0mm - 1.6mm). Improper adjustment may cause failure of the base load. Safety Considerations Specific to Back-Pack Operation The radio frequency energy emitted from a transmitting radio antenna may injure people. The potential for injury is affected by the frequency and power level of the RF energy. A general rule for radios operating in the VHF High Band (around 150 MHz) at about 40 Watts transmitter power is that personnel should be at least 24" (60 cm) from an antenna when it is transmitting. Care should be taken to keep the antenna as far as possible from the body, especially the head, when transmitting. There is no potential for RF energy when the radio is not transmitting or near a high power radio transmitter. Many people have been killed due to contact to a high voltage line through an antenna. Always take extreme care that the antenna does not come in contact with overhead wires or other structures that may have high voltage electrical energy. Be sure to remove the antenna or take the pack off any time lightening is a threat. There is a threat of lightening when thunderstorms are present and when strong winds and clouds are present, even if no lightening has been observed. A "tingly" sensation and hair standing on end, as when static electricity is high, are warning signs of a possible imminent lightening strike. If these occur, take the pack off immediately and assume a crouching or squatting position with minimum contact with the ground, in a low place if possible.

Sitting on a vehicle with rubber tires or wearing rubber shoes does not offer protection from lightening strikes. Sitting inside a fully enclosed vehicle may provide significant protection from injury due to lightening but is not 100% for the path of lightening is unpredictable.

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Shock and Vibration Isolation The SPII has been designed and constructed to be very resistant to shock and vibration. In some situations, the reliability of the SPII unit may be enhanced significantly if it is mounted using shock and vibration isolation techniques and materials. The Back Pack Option is not intended to provide shock and vibration isolation. Back Pack Shock Mount Option An optional shock mounting system is available for our customers who need the flexibility of mounting the SPII on a vehicle, such as a "Quad" or snow mobile and going back pack portable with minimum change over time. The Back Pack Shock Mount Option consists of a mounting plate, which may be secured to the vehicle, shock mounts similar to Aeroflex mounts, and a tray that the SPII with Back Pack Option fits neatly into. Bungee straps or some other securing device should be used to secure the SPII with Back Pack Option in the tray. Mobile Mount / Shipping Case Option The Mobile Mount / Shipping Case Option (MMSCO) provides a rugged case with foam inserts and securing hardware. It normally provides adequate protection and shock and vibration isolation for mounting a SPII and associated equipment on a vehicle and for shipping. Some shipping companies ensure only the contents of containers and not the containers themselves. It would probably be advisable to put this case in an outer container for shipping so the case will be covered by their insurance. A removable antenna mount is provided on the outside of the case for radio communications while the MMSCO is being used on a small vehicle or portably. There is some storage room inside the case for cables, etc. Connectors are provided on the outside of the case for uphole geophone, firing line, and battery charging or external power lines. The standard foam inserts accommodate the SPII, two 7 amp/hour gell cell batteries, and a radio. A foam insert can be supplied to be cut for other radios. If the Pelton Antenna mount is used with half-wave vertical antenna, it is critical that the BA (the large all-thread part of the mount that the antenna base load screws on to) be adjusted properly. The BA must extend above the nut on top of the mount 5/16" +0.00" - 1/16" (7.9mm +0mm - 1.6mm). Improper adjustment may cause failure of the base load.

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SP1Flags Page 12.1.1


01 Mar 06 I:\LISD Manuals\Pelton\ShotPro 2\SPCH12.DOC

SP1FLAGS Computer Program The SP1FLAGS program allows the loading of Flag data into the Shot Pro II. The program reads SEG-P1 files for flag data. SP1FLAGS coverts the data and serially transmits the data to the Shot Pro through the computer port.

Fig 1.

Program start. To start the program, click on "START", "PROGRAMS", double click on the SP1FLAGS Icon.

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01 Mar 06 I:\LISD Manuals\Pelton\ShotPro 2\SPCH12.DOC

Operations:

After starting program, the Com port will have to be set-up.

Com Port Menu - Displays selected Com port number and allows selection of another Com port. Load File Button - Load a SEG-P1 file. Before sending the flag data, select whether to Append or Overwrite the flag data in the Shot Pro. SP1FLAGS gives the operator the choice of sending the first 500 flags to the Shot Pro or individual selection. To select the flags individually, move the pointer to the desired flag and click. To select multiple consecutive flags, move the pointer to the top desired flag, click and hold the shift button down, point to the last flag click. Individual flags can be selected by pressing the Control key down and click on the desired flag. Only the selected flags are serially transmitted to the Shot Pro. If no flags are selected, the first 500 flags are sent.

Fig 2.

Send Button - Sends the flag data to the Shot Pro Decoder. The Shot Pro Decoder has to be in the Flags Menu to accept this data.

Exit Program Button - Press this button to exit the program.

Options Page 13.1.1



RTI – Recording Truck Interface

The SPII Encoder must use the ADVIII VibPro Encoder program to provide the proper link with the recording system. This link allows the recording system to select which SPII Decoder is to fire (Decoder ID). The recording system will also receive the uphole and GPS information from the Decoder. The first step defines main serial communication port number.

Please select serial port number for the Encoder program.

Step 2 – Files, the second page appears that confirms if all files were found for normal program operations. Step 3 – RTI selects type of Recording System Interface. Depends on the recording system you will need to select second serial port or configure Ethernet link. Step 4 is allowing to select serial port driver. The diver is used to share data on the serial bus between the Encoder and other Pelton programs. The last screen of the EncSetup program displays all selections and creates a configuration file when the Finish button is selected. Configuration information is contained in the A3Encode.INI text file, which resides in the main Windows directory.

Com Port 1

RTI-None

RTI-I/O System 2, SCM serial link RTI-I/O System 2, OCM serial link RTI-Raps 1000, serial link RTI-Raps 2000, serial link RTI-I/O System 2000,serial link RTI-I/O System 2000, Ethernet link RTI-GEO-X Aram 24, serial link RTI-Sercel, serial link RTI-Sercel, Ethernet link RTI-Gego MAXIS, serial link RTI-Western-Geco FRS/Q, serial link

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Advance III Vib Pro Encoder Program Introduction

This guide describes how to install, configure, and run the Encoder program.

If the information in the ENCODER.TXT file in the Encoder program subdirectory differs from the information in this section, follow the instructions in the ENCODER.TXT file.

The Encoder program is made to operate on Windows 2000 and XP computers and provides serial interface to the Pelton Vib Pro unit or SPII operating in the Encoder mode. The program shares serial port with other Pelton programs like WVSig32. The Encoder program controls Decoder Groups, Sweep Profiles and provides interface to various types of the Recording Systems. Requirements:

Make sure your PC meets the following requirements:

• Windows 2000 or XP operating system • Pentium II or higher processor • 256 Mbytes of RAM • CD Drive • 2 Gig or higher of available hard drive space • Mouse or other pointing device • SVGA Color Monitor • At least two available serial ports • Access to a network port for a network connection (optional)

Installation and Cabling Setup:

The Encoder program must be installed from Pelton Install CD. To install program, insert CD in your PC, click Start button, select Run and type path to the Setup file. Then click OK button. The first run of the Encoder program will start EncSetup program to generate configuration file. Just follow the program to make settings and click Finish at the end to create new configuration file. To change the Encoder configuration run EncSetup program. Make sure the Encoder program is not running the same time! Cabling:

The corresponding Com Port on the PC with the Encoder program must be connected to the SPII Encoder. Changing configuration settings:

To change the Encoder configuration exit the Encoder program and run EncSetup program.

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Operation To start the Encoder program click on the icon or shortcut. The program shows "splash" window with status bar on the bottom to indicate loading progress. The program first tries to locate and start Pelton serial server - PelComOs. If it is not found then Encoder will try to access serial port directly and sharing serial data is not allowed in this mode. The program dialog window always resides in the right bottom corner of the screen and is shown on the picture below. Edit menu Includes: Swp Profiles 1 –

50, Groups, Auto Functions list and etc

Sweep Profile selector

Options: For SPII,SP1-SP14,SP-RTI

Similarities selector

Not in use for SPII (none)

Current sweep and sweep profile

Displays value selected for the current (running) or for next sweep

Status window and Sweep ID

Encoder status and sweep ID

Extend dialog button

Extends Encoder dialog with additional options: SP jump and Position request

Log window Extended status display, shows received PSS and confirmation messages

Last event window

Double click displays PSS status window

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The click on the "<|" button extends Encoder dialog box and gives the option: The option is Position request box. Five buttons allowing to request position information from Group A, B, C, D or individual Decoder. To restore Encoder dialog box click on "|>" button. Edit menu – Sweep Profiles

The Previous and Next buttons rotating the Sweep Profile number. Sweep number field has a range for value: 1- 16, and Crew number value can be anything from 0 to 99 for SPII.

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Edit menu – Groups

To move/remove shooting unit (Decoder ID #) from one group to another group click on the vibrator number, hold left mouse button down and move it. Release button above desired place. In the Touch screen mode moving vibrator is different - click on vibrator to select then click to desired group to place. The Add Unit and Remove buttons helps to organize this screen. Type in the shooting unit (Decoder ID #) number to add/remove and click on Add or Remove button. Cancel restores all groups in original position. If the Encoder program is working with the SPII Encoder place just one Decoder ID # in each group. Edit menu - Auto Functions: Not applicable with SPII

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Edit menu - Checksums

The checksum control window is used to setup checksum control during encoder operations. If the program detects the difference in checksums it warns the operator. Recommended set-up: Checksum control disabled. Edit menu – Clock Status: Not applicable with SPII

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Edit menu – PSS Status

This dialog keeps track of received PSS messages for each unit in the crew. If needed, all or individual counters can be cleared. Retrieve PSS: Not applicable with SPII

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RTI – Pelton Messaging Protocol for VibPro Introduction: The messaging protocol documented here, is based upon the “A2” messaging protocol for the Advanced 2. The messages listed here are all the messages used with the VibPro Encoder and VibPro Encoder Program. Document Conventions and Notes: This document describes the message protocol for communication between a Recording System and the Pelton VibPro Encoder. Communications with the ShotPro is through the VibPro Encoder. All of the data fields use Hexadecimal format unless otherwise stated. One of the following methods is used to describe the message contents: • Field Name with size in bytes in parentheses appended—e.g., Sz(2). • Literal Characters—e.g., ‘I’. • The first two bytes are ASCII “A2” (Encoder), or “RS” (Recording System). • All other data fields are hexadecimal format unless otherwise stated. • ASCII Pattern enclosed in quotes—e.g., "DDMM.mmmm". This applies to the GPS Information Message: A2 Sz(2) Id(2) Version(2) . . . "hhmmss" , "DDMM.mmmm" , Open(4) . . . * ChkSum(1) Notes: • The two bytes ‘A2’ appear as the first two bytes in the message. • The Id field occupies the 4th and 5th bytes in the message whatever its

actual value. • The commas, spaces and the asterisk literals are shown for clarity only,

and are not part of the message. • The time field ‘hhmmss’ is an ASCII representation of the time, not an

integer encoding. All messaging will be via an RS232 port using settings of 19200 Baud, No Parity, 8 Data Bits, and 1 Stop Bit. Message Contents Recording System to Pelton System Messages Message ID Message and Version 0000 Revision Request 0001 Shot Message 0002 Sequence Code

0003 Request Message (Not Used) 0004 Parameter (Not Used) 0005 Abort (Not Used) 0006 Vibrator/ShotPro GPS Position Request 0007 Support Position Request (Not Used) 0008 Decoder GPS Averaging Mode Select (Not Used) 0009 Recording System Ready

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Pelton Encoder to Recording System Messages

Message ID Message and Version 0000 Verification 0001 GPS Information Version 0001 0001 GPS Information (Not Used) Version 0002 0001 GPS Information Version 0003 0002 Group Ready Information Version 0001 0002 Group Ready Information, XYZ (Not Used) Version 0002 0002 Group Ready Information, XYZ Version 0003 0003 ESG PSS Information 0004 Vibrator PSS Information 0005 Vibrator PSS Correlation 0006 Revision Response 0007 Abort Response (Not Used) 0008 Message (Not Used) 0009 ShotPro PSS Information Message

Recording System to Pelton System Messages Notes: Each message has four fields with a common description. They are: Sz This field contains the number of bytes to follow. The byte count

starts with the Id field and includes the ChkSum byte at the end of the message.

Id This field contains the identifying number for the message. Its value is specified in the line above the field description.

Version This field contains the revision level of the particular message. It does not need to be the same for every message since individual messages may be revised independently of other messages. The initial release of the new messaging system will have each message version set to 1.

ChkSum This field is calculated by forming the exclusive or—XOR—of all bytes starting with the Id field and including all bytes up to the ChkSum field. For the Revision Request Message, therefore, the ChkSum will contain the XOR value of the Id, Version, and Revision fields.

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Revision Request Message - Id = 0000:

RS Sz(2) Id(2) Version(2) Revision(2) ChkSum(1)

This message requests the Pelton System to return the revision level of the messaging system in use. The first byte of the revision will contain major revision level; the second byte will contain minor revisions or patches to the major revision. It should be sent during startup to initialize the Recording System to employ a revision level compatible with that of the Pelton System in use. The revision number field identifies the revision level of the Recording System messaging system. The first two digits reflect the major revision level, while the last two digits reflect minor changes or “patches” to the firmware. This text reflects major revision level 02 and the first release will have a revision number of 0201. The response message (Pelton to Recording System message Id number 6) should be sent immediately upon receipt of this message. As of June 13, 2002, the release and version number will be 0301. Some recording systems do not require this exchange of messages to be implemented. The response message is sent to selected Recording Systems. Example Message ID=0000 Version=1 Rev=0201: 5253000700000001020102 52 - ASCII for “R” 53 - ASCII for “S” 0007 - Sz - size is 7 bytes 0000 - ID - ID is 0000 0001 - Ver - Version is 1 0201 - Rev - Major revision is 2 release number is 1 02 - ChkSum - XOR check sum of ID, Ver, & Rev =02




Shot Message - Id = 0001:

RS Sz(2) Id(2) Version(2) ShotCoordType(1) ShotCoordSize(1) ShotCoordInfo(?) ShotId(4) EpId(4) File(4) ChkSum(1)

This message must be sent before the start of each shot. The information contained in this message is used by the Pelton Computer Programs, and for HFVS. The EpId field will contain the number (starting from 1 to 99 Dec) of the energy point in the sequence of energy points that make up the shot. The File field will contain the tape file number (0-9999 Dec) used for recording the data of the specified shot or EP. A file number of 0 indicates that no data will be recorded. The file number of the final stack will be used for interim Eps. The ShotCoordType Force to 1. This field is ignored. The ShotCoordSize field contains the number of bytes used to express the shot point location in the designated coordinate system. Force to 8. This field is ignored. The ShotCoordInfo field contains the actual shot point location. For type 1 ShotCoordType the ShotCoordInfo is Line (4 bytes) and Station (4 bytes) numbers. Example Message ID=0001 Version=1: 5253001B000100010108000000000000011800000013000000210000001230 52 - ASCII for “R” 53 - ASCII for “S” 001B - Sz - size is 27 bytes 0001 - ID - ID is 0001 0001 - Ver - Version is 1 01- ShotCoordType is 1 08- ShotCoordSize is 8 bytes 00000000- Line position = 0.0 00000118- Station position = 28.0 00000013- Shot ID = 19 00000021- EP ID = 33 00000012- File # = 18

30 - ChkSum - XOR check sum of ID, Ver, ShotCoordType Size, Line & Station, Shot ID, EP ID, and File # = 30hex

Other Implementation and Behavior Notes: The Encoder program stores the shot data, but does NOT send out a new Start Code message. After receiving this message, the Encoder program sends a DMA message with the shot data to the Vib Pro Encoder. If this message is sent after a sweep starts, there could be a collision between messages, if the options Delayed PSS or Retransmit Missing PSS are selected. The Vib Pro Encoder could optionally send these two messages to the Encoder program after the sweep starts.




Sequence Code Message - Id = 0002:

RS Sz(2) Id(2) Version(2) SequenceNumber(1) Serial Number(1) ChkSum(1)

This message will contain information for the next shot. The Recording System must send this message about 1 second before the start command is sent to the Encoder. With the Shot Pro Encoder if the message is sent during the previous shot, it must be sent after Time Break and before 1 second after Time Break, or it may be sent 3 seconds after Time Break. It will not contain a shot or EP number since these will not have been determined at the time of transmission. For certain selected recording systems, the response message (Pelton to Recording System message number 0) will be sent immediately upon receipt of this message. With the Shot Pro if the message is sent during the previous shot, then the response message will be generated after Shot Pro message 9 is sent to the recorder. The SequenceNumber field contains the number of the Sweep Profile to be used for the next shot. The Decoder Group associated with the selected Sweep Profile will fire. This SequenceNumber must be between 1 and 50. If the number is out of this range, the Encoder program will select Sweep Profile number 1. The actual number selected will be in the Verification Message, if it is sent. The Serial Number field will be an identifier attached by the recording system and would be returned in the Pelton System Verification message, if sent, to serve as a cross check on the verification. The Encoder program does not use this number. Example Message ID=0002 Version=1: 5253000700020001631979 52 - ASCII for “R” 53 - ASCII for “S” 0007 - Sz - size is 7 bytes 0002 - ID - ID is 0002 0001 - Ver - Version is 1 63 - Sequence Number =99 19 - Serial Number = 25 79 - ChkSum - XOR check sum of ID, Ver, Seq # & serial Number =79 Request Message - Id =0003: Not Used. Parameter Message - Id = 0004: Not Used. Abort Message - Id = 0005: Not Used.




Vibrator/ShotPro GPS Position Request Message - Id = 0006: RS Sz(2) Id(2) Version(2) Vibrator#/ShotPro#(1) Group#(1) ChkSum(1) The Vibrator# / ShotPro# field identifies the requested Vibrator or ShotPro Unit by number, range : 0 - 15 (0x00 - 0x0F). The Group# field identifies the Vibrator’s Group Number. Valid entries are: 0 for Group A, 1 for Group B, 2 for Group C, and 3 for Group D. Example Message ID=0006 Version=1 5253000700060001040003 52 - ASCII for “R” 53 - ASCII for “S” 0007 - Sz - size is 7 bytes 0006 - ID - ID is 0006 0001 - Ver - Version is 1 04 - Shot Pro Id # 4 00 - Group A 03 - ChkSum - XOR check sum of ID, Ver, Shot Pro Id & Group =03 Other Implementation and Behavior Notes: The Encoder program does not wait for a response from the decoder(s). If a valid group number (0-3) is in the Group field, then a position request is sent to ALL the decoders in that group. If a group number greater than 3 is in the Group field, then a position request is only sent to the decoder number that is indicated by this message. The Position message returned by the Vibrators is sent back during PSS time. The Vibrator number determines PSS time, so, there will be no message collisions. If there are multiple Shot Pro decoders in a group, and all their positions are requested, then there will be message collisions, as the Shot Pro decoders will all transmit at about the same time. Caution: If position request is sent to a decoder that does not exist, the Recording System will never receive a response. Even if a decoder exists, there is the possibility that the Recording System will not receive a response. Shot Pro firmware before version 3.008 does not support Position Requests. Support Position Request - Id = 0007: Not Supported. Decoder GPS Averaging Mode Select Message - Id = 0008: Not Used.




Recording System Ready Message (Version 0001) - Id = 0009: This message indicates that the Recording System is ready to process the next shot, or further commands from the encoder. The Recording System must used this message if the Group Ready Messages are to be queued by the Encoder program. RS Sz(2) Id(2) Version(2) Data(1) ChkSum(1) RS - Header, indicates message from Recording System. Sz - 0006. From Id to Chksum. Id - 0009. Version - Initially for this message is 0001. Data - Currently 00. For future use. ChkSum - XOR of message from IO thru Data. Example Message ID=0009 Version 0001 52 53 00 06 00 09 00 01 00 0F 52 - ASCII for “R” 50 - ASCII for “S” 0006 - Sz - size is 6 bytes 0009 - ID - ID is 0009 0001 - Ver - Version is 1 00 - Null data byte. 0F - ChkSum - XOR check sum of ID, Ver, Data = 0F hex. Other Implementation and Behavior Notes: The main purpose of this message is for managing multiple groups of vibrators using Source Driven Acquisition. Normally, the Group Ready message is sent to the Recording System when it is received by the Encoder program. When multiple groups of vibrators are used, more than one group of vibrators can send a ready message before the Recording System can act upon the message. In this case, the newer ready message can be lost, and will need to be resent. The Encoder program can, if so configured, queue these ready messages. The Recording System Ready message will cause the Encoder program to send the oldest ready message that it holds. If no messages are held in the queue, then the next ready message that is received will be sent on to the Recording System. Pelton Encoder to Recording System Messages The Sz, Id, Version, and ChkSum fields are as described for the Recording System to Pelton messages. The messages from the VibPro Encoder program will use an ASCII “A2” as the first two characters. The ShotPro Encoder is not supported by the VibPro system.




VibPro Encoder Messages Verification Message - Id = 0000:

A2 Sz(2) Id(2) Version(2) Sequence Number ID (1) Serial Number(1) ChkSum(1)

This message verifies the receipt of the Sequence Code Message ID=0002, to selected Recording Systems. This message should be returned immediately upon receipt of the Sequence Code Message. The SerialNumber field identifies the particular sequence number message being verified. At most one sequence number message will be pending, so the SerialNumber field provides a check that the two systems are still in synch. Note: The Sequence number returned in this example could not be 99. The value would be whatever sequence number was actually used. The sequence number passed from the Recording System must be between 1 and 50. If it is not, then 1 is actually used. The 1, in this case, is what would be returned in this Verification Message. Example Message ID=0000 Version=1 41 32 0007 0000 0001 63 19 7B 41 - ASCII for “A” 32 - ASCII for “2” 0007 - Sz - size is 7 bytes 0000 - ID - ID is 0000 0001 – Ver - Version is 1 63 - Sequence # 99 19 - Serial number is 25 7B - ChkSum - XOR check sum of ID, Ver, Seq # & Serial # =7B hex GPS Information Message - Id = 0001: Version 0001

A2 Sz(2) Id(2) Version(2) Unit#(1) ShotId(4) EpId(4) $GPGGA , "hhmmss" , "DDMM.mmmm" , "N" , "DDDMM.mmmm" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * ChkSum(1)

GPS Information Message - Id = 0001: Version 0003

A2 Sz(2) Id(2) Version(2) Unit#(1) ShotId(4) EpId(4) $GPGGA , "hhmmss" , “_YYYYYYYY" , "N" , "_XXXXXXXXX" , "W" , "q" , "ss" , "H" , "±ZZZZ.Z" , "M" , , , * ChkSum(1)

Note: Underscore in Y and X fields represent space for minus sign, if negative, otherwise, a digit can be there. Y = Northing, and X = Easting. There is an implied decimal point before the last digit.

The following is for reference, and an example, as the differences are the version number, and the Average Mode:




GPS Information Message - Id = 0001: Version 0002 Not Used

A2 Sz(2) Id(2) Version(2) Unit#(1) ShotId(4) EpId(4) $GPGGA , "hhmmss" , "DDMM.mmmm" , "N" , "DDDMM.mmmm" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * AvgMode(1) ChkSum(1)

The Version Number for this message is 0002. Unit # 0-F hex (0-15dec) represents Vibrator # 0-15. This message returns the GPS information for a specified shot and EP. Note: that the commas and the asterisk are literals included in the message. The ShotId and EpId will match the ShotId and EpId field of a previous Recording System shot message. The hhmmss field is an ASCII representation of the collection time. The DDMM.mmmm and N fields are ASCII representations of the latitude of the vibrator Shot Pro#. Note that the N field may be either ‘N’ or ‘S’—the name N does not imply either. Similarly, the DDDMM.mmmm (note the additional ‘D’) and W fields provide an ASCII representation of the longitude of vibrator Unit#. The W field may, of course, contain either ‘E’ or ‘W’. The q field has three valid values: ‘0’, ‘1’, and ‘2’ representing invalid, GPS, and DGPS respectively. The ss field contains an ASCII representation of the number of satellites used in obtaining the position information. The H field contains an ASCII digit showing the HDOP (Horizontal Dilution of Precision) in fractional units. The ±AAAA.d field contains an ASCII representation of the elevation of the vibrator. Note that the sign indicator is always present (and almost always ‘+’). The M field contains either ‘M’ or ‘F’ indicating whether the altitude is given in Meters or Feet. The AvgMode field identifies the selected Averaging Mode for the Vibrator GPS Interface Card. The data is in hexadecimal format. 00 - Last: the Latest Position 01 - Best: the best Position 02 - Avg.: the average Position

Example Message ID=0001 Version=2: 4132004A000100020000000000000000002447504747412C3136313833392C333634332E333131302C4E2C30393730362E323332302C572C322C30342C322C2B303333382E302C4D2C2C2C2A0125 41 - ASCII for “A” 32 - ASCII for “2” 004A- Sz - size is bytes 0001 - ID - ID is 0001 0002 - Ver - Version is 2 00 - Vibrator # 0 00000000 - Shot ID = 0 00000000 - EP ID = 0 2447...2C2C2A - ASCII GPS message- (Note: this is “NO DATA”, and spaces, if no data have been received.)

$GPGGA,161839,3643.3110,N,09706.2320,W,2,04,2,+0338.0,M,,,* 161839 - GPS time - 16 hrs, 18 min 39 sec 3643.3110,N - Latitude 36°43.3110’N 09706.2320,W - Longitude 097°06.2320’W 2 - quality = 2 04 - satellites =4 2 - DOP =2 +0338.0, M - elevation = 338.0 meters ,,, - blank fields, Geoidal Separation, Age of Diff. GPS, Ref ID # * - end of data no $GPGGA checksum 01 - Average Mode is set to 1 25 - ChkSum - XOR check sum.




Group Ready Information Message - Id = 0002: Version 0001

A2 Sz(2) Id(2) Version(2) Group#(1) GroupDecoders(4) ReadyDecoders(4) $GPGGA , "hhmmss" , "DDMM.mmmm" , "N" , "DDDMM.mmmm" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * ChkSum(1)

This message returns the CENTER GRAVITY Position information for a group. This message is also returned in response to the Position Request message. If there is no coordinate data to return, then instead of the “$GPGGA,” there will be “NO DATA,” and the rest of the message will be spaces, until the “*” and the null and the ChkSum.

Version Number – Initially for this message is 0001.

Group – The field range is 0 – 3. Note: Plan to support 32 groups in the future.

GroupDecoders – This field returns the decoder numbers configured for the group in the encoder setup. Each bit in the four-byte field corresponds to a specific decoder number. The Least Significant Bit is decoder number 1 and the field value would be 0x00000001. Note: This field is set to 0, if this message is sent in response to a position request message.

ReadyDecoders – This field returns the actual decoder numbers that reported ready in this group. This may differ from the GroupDecoders field if one or more vibrators were not ready. The bit coding for this four-byte field is the same as above. Note: If this field only has one decoder in it, then this message is in response to a position request message. Note: The commas and asterisk are literals included in the message. hhmmss - This field is an ASCII representation of the collection time for the lead vibrator of the group.

DDMM.mmmm and N – These fields are ASCII text of the computed average latitude of the group. Note that the N field may be either ‘N’ or ‘S’—the name N does not imply either.

DDDMM.mmmm (note the additional ‘D’) and W – These fields provide ASCII text of the computed average longitude of the group. The W field contains either ‘E’ or ‘W’.

q – This is the quality field and has three valid values: ‘0’, ‘1’, and ‘2’ representing invalid, GPS, and DGPS respectively. The reported value will represent the lowest value received from any member of the group.

ss – ASCII text of the number of satellites used in obtaining the position information. The reported value is the lowest value received from any member of the group.

H – ASCII digit showing the HDOP (Horizontal Dilution of Precision) in fractional units. The reported value is the lowest value received from any member of the group. ±AAAA.d – ASCII text of the computed average elevation of the group. Note that the sign indicator is always present (and almost always ‘+’). M – This field contains either ‘M’ or ‘F’ indicating whether the altitude is given in Meters or Feet.

Group Ready Information Message, xyz - Id = 0002: Version 0002 Not Used.




Group Ready Information Message, xyz - Id = 0002: Version 0003

A2 Sz(2) Id(2) Version(2) Group#(1) GroupDecoders(4) ReadyDecoders(4) $GPGGA , "hhmmss" , " YYYYYYYY" , "N" , " XXXXXXXXX" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * ChkSum(1)


Version Number – For this message is 0003.



ReadyDecoders – This field returns the actual decoder numbers that reported ready in this group. This may differ from the GroupDecoders field if one or more vibrators were not ready. The bit coding for this four-byte field is the same as above. Note: This field only has one decoder in it, if this message is sent in response to a position request message. Note: The commas and asterisk are literals included in the message.

hhmmss - This field is an ASCII representation of the collection time for the lead vibrator of the group.

YYYYYYYY and N – These fields are ASCII text of the computed average latitude of the group, converted to the Northing measurement. The leading space will have a minus sign if the number is negative. Note that the N field may be either ‘N’ or ‘S’— the name N does not imply either. There is an implied decimal point before the last digit.

XXXXXXXXX and W – These fields provides ASCII text of the computed average longitude of the group, converted to the Easting measurement. The leading space will have a minus sign if the number is negative. The W field contains either ‘E’ or ‘W’. There is an implied decimal point before the last digit.



H – ASCII digit showing the HDOP (Horizontal Dilution of Precision) in fractional units. The reported value is the lowest value received from any member of the group.

±ZZZZ.z – ASCII text of the computed average elevation of the group. Note that the sign indicator is always present (and almost always ‘+’).

M – Either ‘M’ or ‘F’ indicating whether the altitude is given in Meters or Feet.




ESG PSS Information Message - Id = 0003:

A2 Sz(2) Id(2) Version(2) Spare(1) ShotId(4) EpId(4) SeqNo(1) SwpNo(1) SwpMode(1) SwpGenChkSum(1) Spare(3) ChkSum(1)

Note: Spare (1) and Spare (3) are always zero. This message, along with the next two messages, constitutes the Enhanced Post Sweep Service messages. This message contains the Encode Sweep Generator data. Normally, the ESG data is sent followed by the individual vibrator information messages. However, it is possible for the messages to be sent in a different order. The Post Sweep Service messages are sent after each sweep and may or may not include correlation data for each vibrator. In addition to the usual protocol fields, this message contains the following information: The ShotId and EpId correspond to the ShotId and EpId for the current sweep that was sent with the Shot Message that announced the start of the current sweep. The SeqNo field corresponds to the sequence code (1 – 50) sent in the Sequence Code message that was sent for this sweep. The SwpNo field contains the current sweep number. The Swp Mode indicates the mode of operation; 1 is Keyboard Mode, 2 is Stored Parameter Mode, 3 is Stored Values Mode The SwpGenChkSum field contains the checksum generated by the ESG for the entire message. It should not be confused with the ChkSum field. Example Message ID=0003 Version=1: 41320015000300010000000000000000000000012F0000002C 41 - ASCII for “A” 32 - ASCII for “2” 0015- Sz - size is 21 bytes 0003 - ID - ID is 0003 0001 - Ver - Version is 1 00 - Spare 00000000 - Shot ID is 0 00000000 - EpId is 0 00 - Sequence # is 0 00 - Sweep # is 0 01 - Sweep Mode is 1 2F - Sweep Generator Checksum is 2F 000000 - Spare 2C - ChkSum - XOR check sum




Vibrator PSS Information Message - Id = 0004:

A2 Sz(2) Id(2) Version(2) Vib#(1) ShotId(4) EpId(4) PSSType(1) SwpNo(1) VibChkSum(1) PkPhase(1) PkForce(1) AvgPhase(1) AvgForce(1) PkDist(1) AvgDist(1) SweepChkSum(1) Spare(4) ChkSum(1)

The Vibrator PSS Information messages normally follow the ESG message. One message for each active vibrator is sent after each sweep. Normally, the vibrator messages will arrive in sequence, but this ordering is not guaranteed. In addition to the usual protocol fields, these messages have the following fields: The Vib# field identifies the current vibrator or Shot Pro by number. The ShotId and EpId correspond to the ShotId and EpId for the current sweep that was sent with the Shot Message that announced the start of the current sweep. The PSSType field identifies the Post Sweep Service Type. The SwpNo field identifies the current sweep by number. The VibChkSum field contains the vibrator checksum. It should not be confused with the ChkSum field. The PkPhase field contains the unencoded peak phase value for the sweep in degrees. The AvgPhase field contains the unencoded sweep average phase in degrees. The range for these fields is from -179 to 179 degrees. The PkForce field contains the unencoded peak force value for the sweep. The AvgForce field contains the sweep unencoded average force value. The range for these fields is from 0 to 200%. The PkDist field contains the unencoded peak distortion value for the sweep. The AvgDist field contains the unencoded average distortion value for the sweep. The range for these fields is from 0 to 99%. The SwpChkSum field contains the sweep checksum. It should not be confused with the ChkSum field. The Spare (4) is all 0. NOTE: If this is a re-transmission of a missing PSS message, the ShotId, and EpId fields are INVALID, as this information is not persistent in the Encoder program. Example Message ID=0004 Version=1: 4132001C0004000100000000000000000020004010013F382010C9010000008B 41 - ASCII for “A” 32 - ASCII for “2” 001C- Sz - size is 28 bytes 0004 - ID - ID is 0004 0001 - Ver - Version is 1 00 - Vibrator # is 0 00000000 - Shot ID is 0 00000000 - EpId is 0 20 - PSS type is 20 00 - Sweep # is 0 40 - Vibrator Checksum is 40 10 - Peak phase is 16 degrees 01 - Average Phase is 1 degrees 3F - Peak force is 63% 38 - Average force is 56% 20 - Peak distortion is 32% 10 - Average distortion is 16% C9 - Sweep Generator Checksum is C9 01 – Spare – ignore. 00 – Spare – ignore. 00 – Spare – ignore. 00 – Spare – ignore. 8B - ChkSum - XOR check sum.




Vibrator PSS Correlation Message - Id = 0005:

A2 Sz(2) Id(2) Version(2) Vib#(1) ShotId(4) EpId(4) Correlation(128) Gain(2) ChkSum(1)

The Vibrator PSS Correlation message contains correlation data for each vibrator. This message has the following fields: The Vib# field identifies the current vibrator by number. The ShotId and EpId correspond to the ShotId and EpId for the current sweep that was sent with the Shot Message that announced the start of the current sweep. The Correlation field contains 128 bytes of biased correlation wavelet data. The Gain field contains the gain factor in MSB LSB order. It is a scaled number. To obtain the actual gain, convert it to float type, then divide the value here by 32768. Process the correlation data by multiplying each data byte by the processed gain value. The true correlation wavelet is obtained by multiplying each sample in the Correlation field by the gain value. Example Message ID=0005 Version=1: 4132009000050001000000000000000000FE000100FDFBFBFCFFFFFEFBFAFBFE0101FFFCFCFF03050401FF000408080501FF0206090701FCFB000505FFF6F2F4FC00FDF2E7E5EEFC01F5DECCD3FA356A7F6A34F9D3CDDEF501FCEFE5E6F1FC00FCF5F2F5FD040501FCFBFF0509080400000307080602FFFF02040401FDFCFCFF0100FDFAFAFBFEFFFFFDFBFBFD000100FD037FF9 41 - ASCII for “A” 32 - ASCII for “2” 0090- Sz - size is 144 bytes 0005 - ID - ID is 0005 0001 - Ver - Version is 1 00 - Vib # is 0 00000000 - Shot ID is 0 00000000 - EpId is 0 FE0001... 0100FD - Correlation data 2’s complement; 128 samples

037F - Gain word applied to all correlation samples. The actual gain is 895/32768, which equals 0.027313232421875.

F9 - ChkSum - XOR check sum.




Revision Response Message - Id = 0006:

A2 Sz(2) Id(2) Version(2) Revision(2) ChkSum(1)

This message returns the revision level software/firmware in use by the Pelton System. The Version field is specious in that the Recording System must be prepared to accept this message whatever the value in the Version field. The system cannot know the version level of each message until after the Revision Request message has been sent and the Revision Request message is received. The Version field is included here for consistency. This message should be formulated and sent immediately upon receipt of the Revision Request Message as the Recording System requires this message to properly initialize the messaging system. This document reflects Revision level 2. Example Message ID=0006 Version=1 4132000700060001020104 41 - ASCII for “A” 32 - ASCII for “2” 0007 - Sz - size is 7 bytes 0006 - ID - ID is 0006 0001 - Ver - Version is 1 0201 - Rev - Major Revision is 2 release number is 1 04- ChkSum - XOR check sum of ID, Ver, & Revision =04 hex Abort Response Message - Id = 0007: Not Used. Message - Id = 0008: Not Used.




SHOTPRO PSS Information Message - Id = 0009: A2 Sz(2) Id(2) Version(2) ShotPro#(1) CTB(2) FirstPick(2) FireLineResist(2) GeophoneResist(2) Status(1) ChkSum(1) The Shot Pro data will be sent after each shot. The ShotPro# field identifies the current ShotPro by number, range : 0 - 15. The CTB field contains Confirmed Time Break data in microseconds. The FirstPick field contains Up-hole Geophone Pick Time data in 500 µsec per step. If the unscaled value is < 1 or > 500, then the First Pick value is invalid. The FireLineResistance and GeophoneResistance fields contains results of measurements, status of the results, and scaling information for the resistance values. The Status field contains status and scaling information for the resistance values. Resistance Status Bits: These bits are the least significant 5 bits of both resistance fields. Bits 0, 1 are the scaling values, bit 2 is Range checking, bit 3 is Limits checking. Bit 4 of the Geophone resistance field is the battery status bit. Scaling bits: Value Calculation 0 No scale, leave value as is. 1 Resistance = ((Raw Value - 2176) * 5120 + 128) / 256000 2 Resistance = ((Raw Value - 2056) * 5106 + 128) / 25600 3 Resistance = ((Raw Value - 2048) * 5172 + 128) / 2560 Range bit: 0 Value is in range

1 Value is out of range Limits bit: 0 Value is out of limits

1 Value is in limits Battery bit: 0 Battery is ok.

1 Battery is low. The bits in the Status field contains data that is related to the scaling of the geophone voltage information, whether or not it is clipped, and if this PFS is being retransmitted. Bit 4 (from 0) indicates if the geophone signal is clipped or not. 0 = Not Clipped, and 1 = Clipped. Bit 2 indicates if the PFS is retransmitted or not. 0 = Normal PFS, 1 = Retransmitted PFS. The signal data is not sent to the recording system. From the original ShotPro, Bit 3 is always 0. From the ShotPro II, if bit 3 = 1, then .25 mSec is added to the First Pick time.

Example Message ID=0009 Version=1 4132000F000900010100C8001C00320BB8015D 41 - ASCII for “A” 32 - ASCII for “2” 000F - Sz - size is 15 bytes 0009 - ID - ID is 0009 0001 - Ver - Version is 1 01 - Shot Pro # is 1 00C8 - CTB is 200 microseconds 001C - First Pick is 14 milliseconds 0032 - Fire Line Resistance – calculates to invalid value. In Range, out of

Limits. 0BB8 - Geophone Resistance – calculates to 187 ohms. In Range, in Limits. 01 - Status is 01. Bit 4 = 0, so Geophone signal is not clipped. 5D- ChkSum - XOR check sum of ID, Ver, ShotPro#, CTB, FP, Res& Status =5D hex

Document History: 09/25/2002 KSR Document started. 10/16/2002 KSR Added note regarding the retransmission of missing PSS messages. 12/08/2003 KSR Added further status information for ShotPro PFS message, which

includes a change for ShotPro II




RTI – Pelton Messaging Protocol for VibPro – I/O Introduction: The messaging protocol documented here, is based upon the “A2” messaging protocol for the Advanced 2. The messages listed here are all the messages used with the VibPro Encoder and VibPro Encoder Program. Document Conventions and Notes: This document describes the message protocol for communication between a Recording System and the Pelton Vib Pro Encoder. Communications with the Shot Pro is through the Vib Pro Encoder. All of the data fields use Hexadecimal format unless otherwise stated. One of the following methods is used to describe the message contents: • Field Name with size in bytes in parentheses appended—e.g., Sz(2). • Literal Characters—e.g., ‘I’. • The first two bytes are ASCII “A2” (Encoder), or “RS” (Recording System). • All other data fields are hexadecimal format unless otherwise stated. • ASCII Pattern enclosed in quotes—e.g., "DDMM.mmmm". This applies to the GPS Information Message: A2 Sz(2) Id(2) Version(2) . . . "hhmmss" , "DDMM.mmmm" , Open(4) . . . * ChkSum(1) Notes: • The two bytes ‘A2’ appear as the first two bytes in the message. • The Id field occupies the 4th and 5th bytes in the message whatever its

actual value. • The commas, spaces and the asterisk literals are shown for clarity only,

and are not part of the message. • The time field ‘hhmmss’ is an ASCII representation of the time, not an

integer encoding. All messaging will be via an RS232 port using settings of 19200 Baud, No Parity, 8 Data Bits, and 1 Stop Bit. Message Contents Recording System to Pelton System Messages Message ID Message and Version 0000 Revision Request 0001 Shot Message 0002 Sequence Code

0003 Request Message (Not Used) 0004 Parameter (Not Used) 0005 Abort (Not Used) 0006 Vibrator/ShotPro GPS Position Request 0007 Support Position Request (Not Used) 0008 Decoder GPS Averaging Mode Select (Not Used) 0009 Recording System Ready




Pelton Encoder to Recording System Messages

Message ID Message and Version 0000 Verification 0001 GPS Information Version 0001 0001 GPS Information (Not Used) Version 0002 0001 GPS Information Version 0003 0002 Group Ready Information Version 0001 0002 Group Ready Information, XYZ (Not Used) Version 0002 0002 Group Ready Information, XYZ Version 0003 0003 ESG PSS Information 0004 Vibrator PSS Information 0005 Vibrator PSS Correlation 0006 Revision Response 0007 Abort Response (Not Used) 0008 Message (Not Used) 0009 ShotPro PSS Information Message

Recording System to Pelton System Messages Notes: Each message has four fields with a common description. They are: Sz This field contains the number of bytes to follow. The byte count

starts with the Id field and includes the ChkSum byte at the end of the message.

Id This field contains the identifying number for the message. Its value

is specified in the line above the field description. Version This field contains the revision level of the particular message. It

does not need to be the same for every message since individual messages may be revised independently of other messages. The initial release of the new messaging system will have each message version set to 1.

ChkSum This field is calculated by forming the exclusive or—XOR—of all bytes

starting with the Id field and including all bytes up to the ChkSum field. For the Revision Request Message, therefore, the ChkSum will contain the XOR value of the Id, Version, and Revision fields.




Revision Request Message - Id = 0000:

RS Sz(2) Id(2) Version(2) Revision(2) ChkSum(1)

This message requests the Pelton System to return the revision level of the messaging system in use. The first byte of the revision will contain major revision level; the second byte will contain minor revisions or patches to the major revision. It should be sent during startup to initialize the Recording System to employ a revision level compatible with that of the Pelton System in use. The revision number field identifies the revision level of the Recording System messaging system. The first two digits reflect the major revision level, while the last two digits reflect minor changes or “patches” to the firmware. This text reflects major revision level 02 and the first release will have a revision number of 0201. The response message (Pelton to Recording System message Id number 6) should be sent immediately upon receipt of this message. As of June 13, 2002, the release and version number will be 0301. Some recording systems do not require this exchange of messages to be implemented. The response message is sent to selected Recording Systems. Example Message ID=0000 Version=1 Rev=0201: 5253000700000001020102 52 - ASCII for “R” 53 - ASCII for “S” 0007 - Sz - size is 7 bytes 0000 - ID - ID is 0000 0001 - Ver - Version is 1 0201 - Rev - Major revision is 2 release number is 1 02 - ChkSum - XOR check sum of ID, Ver, & Rev =02




Shot Message - Id = 0001:

RS Sz(2) Id(2) Version(2) ShotCoordType(1) ShotCoordSize(1) ShotCoordInfo(?) ShotId(4) EpId(4) File(4) ChkSum(1)

This message must be sent before the start of each shot. The information contained in this message is used by the Pelton Computer Programs, and for HFVS. The EpId field will contain the number (starting from 1 to 99 Dec) of the energy point in the sequence of energy points that make up the shot. The File field will contain the tape file number (0-9999 Dec) used for recording the data of the specified shot or EP. A file number of 0 indicates that no data will be recorded. The file number of the final stack will be used for interim Eps. The ShotCoordType Force to 1. This field is ignored. The ShotCoordSize field contains the number of bytes used to express the shot point location in the designated coordinate system. Force to 8. This field is ignored. The ShotCoordInfo field contains the actual shot point location. For type 1 ShotCoordType the ShotCoordInfo is Line (4 bytes) and Station (4 bytes) numbers. Example Message ID=0001 Version=1: 5253001B000100010108000000000000011800000013000000210000001230 52 - ASCII for “R” 53 - ASCII for “S” 001B - Sz - size is 27 bytes 0001 - ID - ID is 0001 0001 - Ver - Version is 1 01- ShotCoordType is 1 08- ShotCoordSize is 8 bytes 00000000- Line position = 0.0 00000118- Station position = 28.0 00000013- Shot ID = 19 00000021- EP ID = 33 00000012- File # = 18

30 - ChkSum - XOR check sum of ID, Ver, ShotCoordType Size, Line & Station, Shot ID, EP ID, and File # = 30hex

Other Implementation and Behavior Notes: The Encoder program stores the shot data, but does NOT send out a new Start Code message. After receiving this message, the Encoder program sends a DMA message with the shot data to the VibPro Encoder. If this message is sent after a sweep starts, there could be a collision between messages, if the options Delayed PSS or Retransmit Missing PSS are selected. The VibPro Encoder could optionally send these two messages to the Encoder program after the sweep starts.




Sequence Code Message - Id = 0002:

RS Sz(2) Id(2) Version(2) SequenceNumber(1) Serial Number(1) ChkSum(1)

This message will contain information for the next shot. The Recording System must send this message about 1 second before the start command is sent to the Encoder. With the Shot Pro Encoder if the message is sent during the previous shot, it must be sent after Time Break and before 1 second after Time Break, or it may be sent 3 seconds after Time Break. It will not contain a shot or EP number since these will not have been determined at the time of transmission. For certain selected recording systems, the response message (Pelton to Recording System message number 0) will be sent immediately upon receipt of this message. With the Shot Pro if the message is sent during the previous shot, then the response message will be generated after Shot Pro message 9 is sent to the recorder. The SequenceNumber field contains the number of the Sweep Profile to be used for the next shot. The Decoder Group associated with the selected Sweep Profile will fire. This SequenceNumber must be between 1 and 50. If the number is out of this range, the Encoder program will select Sweep Profile number 1. The actual number selected will be in the Verification Message, if it is sent. The Serial Number field will be an identifier attached by the recording system and would be returned in the Pelton System Verification message, if sent, to serve as a cross check on the verification. The Encoder program does not use this number. Example Message ID=0002 Version=1: 5253000700020001631979 52 - ASCII for “R” 53 - ASCII for “S” 0007 - Sz - size is 7 bytes 0002 - ID - ID is 0002 0001 - Ver - Version is 1 63 - Sequence Number =99 19 - Serial Number = 25 79 - ChkSum - XOR check sum of ID, Ver, Seq # & serial Number =79 Request Message - Id =0003: Not Used. Parameter Message - Id = 0004: Not Used. Abort Message - Id = 0005: Not Used.




Vibrator/ShotPro GPS Position Request Message - Id = 0006: RS Sz(2) Id(2) Version(2) Vibrator#/ShotPro#(1) Group#(1) ChkSum(1) The Vibrator# / ShotPro# field identifies the requested Vibrator or ShotPro Unit by number, range : 0 - 15 (0x00 - 0x0F). The Group# field identifies the Vibrator’s Group Number. Valid entries are: 0 for Group A, 1 for Group B, 2 for Group C, and 3 for Group D. Example Message ID=0006 Version=1 5253000700060001040003 52 - ASCII for “R” 53 - ASCII for “S” 0007 - Sz - size is 7 bytes 0006 - ID - ID is 0006 0001 - Ver - Version is 1 04 - Shot Pro Id # 4 00 - Group A 03 - ChkSum - XOR check sum of ID, Ver, Shot Pro Id & Group =03 Other Implementation and Behavior Notes: The Encoder program does not wait for a response from the decoder(s). If a valid group number (0-3) is in the Group field, then a position request is sent to ALL the decoders in that group. If a group number greater than 3 is in the Group field, then a position request is only sent to the decoder number that is indicated by this message. The Position message returned by the Vibrators is sent back during PSS time. The Vibrator number determines PSS time, so, there will be no message collisions. If there are multiple Shot Pro decoders in a group, and all their positions are requested, then there will be message collisions, as the Shot Pro decoders will all transmit at about the same time. Caution: If position request is sent to a decoder that does not exist, the Recording System will never receive a response. Even if a decoder exists, there is the possibility that the Recording System will not receive a response. Shot Pro firmware before version 3.008 does not support Position Requests. Support Position Request - Id = 0007: Not Supported. Decoder GPS Averaging Mode Select Message - Id = 0008: Not Used.




Recording System Ready Message (Version 0001) - Id = 0009: This message indicates that the Recording System is ready to process the next shot, or further commands from the encoder. The Recording System must used this message if the Group Ready Messages are to be queued by the Encoder program. RS Sz(2) Id(2) Version(2) Data(1) ChkSum(1) RS - Header, indicates message from Recording System. Sz - 0006. From Id to Chksum. Id - 0009. Version - Initially for this message is 0001. Data - Currently 00. For future use. ChkSum - XOR of message from IO thru Data. Example Message ID=0009 Version 0001 52 53 00 06 00 09 00 01 00 0F 52 - ASCII for “R” 50 - ASCII for “S” 0006 - Sz - size is 6 bytes 0009 - ID - ID is 0009 0001 - Ver - Version is 1 00 - Null data byte. 0F - ChkSum - XOR check sum of ID, Ver, Data = 0F hex. Other Implementation and Behavior Notes: The main purpose of this message is for managing multiple groups of vibrators using Source Driven Acquisition. Normally, the Group Ready message is sent to the Recording System when it is received by the Encoder program. When multiple groups of vibrators are used, more than one group of vibrators can send a ready message before the Recording System can act upon the message. In this case, the newer ready message can be lost, and will need to be resent. The Encoder program can, if so configured, queue these ready messages. The Recording System Ready message will cause the Encoder program to send the oldest ready message that it holds. If no messages are held in the queue, then the next ready message that is received will be sent on to the Recording System.




Pelton Encoder to Recording System Messages The Sz, Id, Version, and ChkSum fields are as described for the Recording System to Pelton messages. The messages from the VibPro Encoder program will use an ASCII “A2” as the first two characters. The ShotPro Encoder is not supported by the VibPro system. VibPro Encoder Messages Verification Message - Id = 0000:

A2 Sz(2) Id(2) Version(2) Sequence Number ID (1) Serial Number(1) ChkSum(1)

This message verifies the receipt of the Sequence Code Message ID=0002, to selected Recording Systems. This message should be returned immediately upon receipt of the Sequence Code Message. The SerialNumber field identifies the particular sequence number message being verified. At most one sequence number message will be pending, so the SerialNumber field provides a check that the two systems are still in synch. Note: The Sequence number returned in this example could not be 99. The value would be whatever sequence number was actually used. The sequence number passed from the Recording System must be between 1 and 50. If it is not, then 1 is actually used. The 1, in this case, is what would be returned in this Verification Message. Example Message ID=0000 Version=1 41 32 0007 0000 0001 63 19 7B 41 - ASCII for “A” 32 - ASCII for “2” 0007 - Sz - size is 7 bytes 0000 - ID - ID is 0000 0001 – Ver - Version is 1 63 - Sequence # 99 19 - Serial number is 25 7B - ChkSum - XOR check sum of ID, Ver, Seq # & Serial # =7B hex GPS Information Message - Id = 0001: Version 0001

A2 Sz(2) Id(2) Version(2) Unit#(1) ShotId(4) EpId(4) $GPGGA , "hhmmss" , "DDMM.mmmm" , "N" , "DDDMM.mmmm" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * ChkSum(1)

GPS Information Message - Id = 0001: Version 0003

A2 Sz(2) Id(2) Version(2) Unit#(1) ShotId(4) EpId(4) $GPGGA , "hhmmss" , “_YYYYYYYY" , "N" , "_XXXXXXXXX" , "W" , "q" , "ss" , "H" , "±ZZZZ.Z" , "M" , , , * ChkSum(1)

Note: Underscore in Y and X fields represent space for minus sign, if negative, otherwise, a digit can be there. Y = Northing, and X = Easting. There is an implied decimal point before the last digit.

The following is for reference, and an example, as the differences are the version number, and the Average Mode:




GPS Information Message - Id = 0001: Version 0002 Not Used

A2 Sz(2) Id(2) Version(2) Unit#(1) ShotId(4) EpId(4) $GPGGA , "hhmmss" , "DDMM.mmmm" , "N" , "DDDMM.mmmm" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * AvgMode(1) ChkSum(1)

The Version Number for this message is 0002. Unit # 0-F hex (0-15dec) represents Vibrator # 0-15. This message returns the GPS information for a specified shot and EP. Note that the commas and the asterisk are literals included in the message. The ShotId and EpId will match the ShotId and EpId field of a previous Recording System shot message. The hhmmss field is an ASCII representation of the collection time. The DDMM.mmmm and N fields are ASCII representations of the latitude of the vibrator Shot Pro#. Note that the N field may be either ‘N’ or ‘S’—the name N does not imply either. Similarly, the DDDMM.mmmm (note the additional ‘D’) and W fields provide an ASCII representation of the longitude of vibrator Unit#. The W field may, of course, contain either ‘E’ or ‘W’. The q field has three valid values: ‘0’, ‘1’, and ‘2’ representing invalid, GPS, and DGPS respectively. The ss field contains an ASCII representation of the number of satellites used in obtaining the position information. The H field contains an ASCII digit showing the HDOP (Horizontal Dilution of Precision) in fractional units. The ±AAAA.d field contains an ASCII representation of the elevation of the vibrator. Note that the sign indicator is always present (and almost always ‘+’).The M field contains either ‘M’ or ‘F’ indicating whether the altitude is given in Meters or Feet. The AvgMode field identifies the selected Averaging Mode for the Vibrator GPS Interface Card. The data is in hexadecimal format. 00 - Last: the Latest Position 01 - Best: the best Position 02 - Avg.: the average Position Example Message ID=0001 Version=2: 4132004A000100020000000000000000002447504747412C3136313833392C333634332E333131302C4E2C30393730362E323332302C572C322C30342C322C2B303333382E302C4D2C2C2C2A0125 41 - ASCII for “A” 32 - ASCII for “2” 004A- Sz - size is bytes 0001 - ID - ID is 0001 0002 - Ver - Version is 2 00 - Vibrator # 0 00000000 - Shot ID = 0 00000000 - EP ID = 0 2447...2C2C2A - ASCII GPS message- (Note: this is “NO DATA”, and spaces, if no data have been received.)

$GPGGA,161839,3643.3110,N,09706.2320,W,2,04,2,+0338.0,M,,,* 161839 - GPS time - 16 hrs, 18 min 39 sec 3643.3110,N - Latitude 36°43.3110’N 09706.2320,W - Longitude 097°06.2320’W 2 - quality = 2 04 - satellites =4 2 - DOP =2 +0338.0, M - elevation = 338.0 meters ,,, - blank fields, Geoidal Separation, Age of Diff. GPS, Ref ID # * - end of data no $GPGGA checksum 01 - Average Mode is set to 1 25 - ChkSum - XOR check sum.




Group Ready Information Message - Id = 0002: Version 0001

A2 Sz(2) Id(2) Version(2) Group#(1) GroupDecoders(4) ReadyDecoders(4) $GPGGA , "hhmmss" , "DDMM.mmmm" , "N" , "DDDMM.mmmm" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * ChkSum(1)


Version Number – Initially for this message is 0001.



ReadyDecoders – This field returns the actual decoder numbers that reported ready in this group. This may differ from the GroupDecoders field if one or more vibrators were not ready. The bit coding for this four-byte field is the same as above. Note: If this field only has one decoder in it, then this message is in response to a position request message. Note: The commas and asterisk are literals included in the message.

hhmmss - This field is an ASCII representation of the collection time for the lead vibrator of the group.

DDMM.mmmm and N – These fields are ASCII text of the computed average latitude of the group. Note that the N field may be either ‘N’ or ‘S’—the name N does not imply either.

DDDMM.mmmm (note the additional ‘D’) and W – These fields provide ASCII text of the computed average longitude of the group. The W field contains either ‘E’ or ‘W’.



H – ASCII digit showing the HDOP (Horizontal Dilution of Precision) in fractional units. The reported value is the lowest value received from any member of the group. ±AAAA.d – ASCII text of the computed average elevation of the group. Note that the sign indicator is always present (and almost always ‘+’).

M – This field contains either ‘M’ or ‘F’ indicating whether the altitude is given in Meters or Feet.

Group Ready Information Message, xyz - Id = 0002: Version 0002 Not Used.




Group Ready Information Message, xyz - Id = 0002: Version 0003

A2 Sz(2) Id(2) Version(2) Group#(1) GroupDecoders(4) ReadyDecoders(4) $GPGGA , "hhmmss" , " YYYYYYYY" , "N" , " XXXXXXXXX" , "W" , "q" , "ss" , "H" , "±AAAA.d" , "M" , , , * ChkSum(1)

This message returns the CENTER GRAVITY Position information for a group. This message is also returned in response to the Position Request message. If there is no coordinate data to return, then instead of the “$GPGGA,” there will be “NO DATA,” and the rest of the message will be spaces, until the “*” and the null and the ChkSum. Version Number – For this message is 0003.

Group – The field range is 0 – 3. Note: Plan to support 32 groups in the future. GroupDecoders – This field returns the decoder numbers configured for the group in the encoder setup. Each bit in the four-byte field corresponds to a specific decoder number. The Least Significant Bit is decoder number 1 and the field value would be 0x00000001. Note: This field is set to 0, if this message is sent in response to a position request message.

ReadyDecoders – This field returns the actual decoder numbers that reported ready in this group. This may differ from the GroupDecoders field if one or more vibrators were not ready. The bit coding for this four-byte field is the same as above. Note: This field only has one decoder in it, if this message is sent in response to a position request message. Note: The commas and asterisk are literals included in the message. hhmmss - This field is an ASCII representation of the collection time for the lead vibrator of the group.

YYYYYYYY and N – These fields are ASCII text of the computed average latitude of the group, converted to the Northing measurement. The leading space will have a minus sign if the number is negative. Note that the N field may be either ‘N’ or ‘S’—the name N does not imply either. There is an implied decimal point before the last digit.

XXXXXXXXX and W – These fields provides ASCII text of the computed average longitude of the group, converted to the Easting measurement. The leading space will have a minus sign if the number is negative. The W field contains either ‘E’ or ‘W’. There is an implied decimal point before the last digit.



H – ASCII digit showing the HDOP (Horizontal Dilution of Precision) in fractional units. The reported value is the lowest value received from any member of the group.

±ZZZZ.z – ASCII text of the computed average elevation of the group. Note that the sign indicator is always present (and almost always ‘+’).

M – Either ‘M’ or ‘F’ indicating whether the altitude is given in Meters or Feet.




ESG PSS Information Message - Id = 0003:

A2 Sz(2) Id(2) Version(2) Spare(1) ShotId(4) EpId(4) SeqNo(1) SwpNo(1) SwpMode(1) SwpGenChkSum(1) Spare(3) ChkSum(1)

Note: Spare (1) and Spare (3) are always zero. This message, along with the next two messages, constitutes the Enhanced Post Sweep Service messages. This message contains the Encode Sweep Generator data. Normally, the ESG data is sent followed by the individual vibrator information messages. However, it is possible for the messages to be sent in a different order. The Post Sweep Service messages are sent after each sweep and may or may not include correlation data for each vibrator. In addition to the usual protocol fields, this message contains the following information: The ShotId and EpId correspond to the ShotId and EpId for the current sweep that was sent with the Shot Message that announced the start of the current sweep. The SeqNo field corresponds to the sequence code (1 – 50) sent in the Sequence Code message that was sent for this sweep. The SwpNo field contains the current sweep number. The Swp Mode indicates the mode of operation; 1 is Keyboard Mode, 2 is Stored Parameter Mode, 3 is Stored Values Mode The SwpGenChkSum field contains the checksum generated by the ESG for the entire message. It should not be confused with the ChkSum field. Example Message ID=0003 Version=1: 41320015000300010000000000000000000000012F0000002C 41 - ASCII for “A” 32 - ASCII for “2” 0015- Sz - size is 21 bytes 0003 - ID - ID is 0003 0001 - Ver - Version is 1 00 - Spare 00000000 - Shot ID is 0 00000000 - EpId is 0 00 - Sequence # is 0 00 - Sweep # is 0 01 - Sweep Mode is 1 2F - Sweep Generator Checksum is 2F 000000 - Spare 2C - ChkSum - XOR check sum




Vibrator PSS Information Message - Id = 0004:

A2 Sz(2) Id(2) Version(2) Vib#(1) ShotId(4) EpId(4) PSSType(1) SwpNo(1) VibChkSum(1) PkPhase(1) PkForce(1) AvgPhase(1) AvgForce(1) PkDist(1) AvgDist(1) SweepChkSum(1) Spare(4) ChkSum(1)

The Vibrator PSS Information messages normally follow the ESG message. One message for each active vibrator is sent after each sweep. Normally, the vibrator messages will arrive in sequence, but this ordering is not guaranteed. In addition to the usual protocol fields, these messages have the following fields: The Vib# field identifies the current vibrator or Shot Pro by number. The ShotId and EpId correspond to the ShotId and EpId for the current sweep that was sent with the Shot Message that announced the start of the current sweep. The PSSType field identifies the Post Sweep Service Type. The SwpNo field identifies the current sweep by number. The VibChkSum field contains the vibrator checksum. It should not be confused with the ChkSum field. The PkPhase field contains the un-encoded peak phase value for the sweep in degrees. The AvgPhase field contains the un-encoded sweep average phase in degrees. The range for these fields is from -179 to 179 degrees. The PkForce field contains the un-encoded peak force value for the sweep. The AvgForce field contains the sweep un-encoded average force value. The range for these fields is from 0 to 200%. The PkDist field contains the un-encoded peak distortion value for the sweep. The AvgDist field contains the un-encoded average distortion value for the sweep. The range for these fields is from 0 to 99%. The SwpChkSum field contains the sweep checksum. It should not be confused with the ChkSum field. The Spare (4) is all 0. NOTE: If this is a re-transmission of a missing PSS message, the ShotId, and EpId fields are INVALID, as this information is not persistent in the Encoder program.

Example Message ID=0004 Version=1: 4132001C0004000100000000000000000020004010013F382010C9010000008B 41 - ASCII for “A” 32 - ASCII for “2” 001C- Sz - size is 28 bytes 0004 - ID - ID is 0004 0001 - Ver - Version is 1 00 - Vibrator # is 0 00000000 - Shot ID is 0 00000000 - EpId is 0 20 - PSS type is 20 00 - Sweep # is 0 40 - Vibrator Checksum is 40 10 - Peak phase is 16 degrees 01 - Average Phase is 1 degrees 3F - Peak force is 63% 38 - Average force is 56% 20 - Peak distortion is 32% 10 - Average distortion is 16% C9 - Sweep Generator Checksum is C9 01 – Spare – ignore. 00 – Spare – ignore. 00 – Spare – ignore. 00 – Spare – ignore. 8B - ChkSum - XOR check sum.




Vibrator PSS Correlation Message - Id = 0005:

A2 Sz(2) Id(2) Version(2) Vib#(1) ShotId(4) EpId(4) Correlation(128) Gain(2) ChkSum(1)

The Vibrator PSS Correlation message contains correlation data for each vibrator. This message has the following fields: The Vib# field identifies the current vibrator by number. The ShotId and EpId correspond to the ShotId and EpId for the current sweep that was sent with the Shot Message that announced the start of the current sweep. The Correlation field contains 128 bytes of biased correlation wavelet data. The Gain field contains the gain factor in MSB LSB order. It is a scaled number. To obtain the actual gain, convert it to float type, then divide the value here by 32768. Process the correlation data by multiplying each data byte by the processed gain value. The true correlation wavelet is obtained by multiplying each sample in the Correlation field by the gain value. Example Message ID=0005 Version=1: 4132009000050001000000000000000000FE000100FDFBFBFCFFFFFEFBFAFBFE0101FFFCFCFF03050401FF000408080501FF0206090701FCFB000505FFF6F2F4FC00FDF2E7E5EEFC01F5DECCD3FA356A7F6A34F9D3CDDEF501FCEFE5E6F1FC00FCF5F2F5FD040501FCFBFF0509080400000307080602FFFF02040401FDFCFCFF0100FDFAFAFBFEFFFFFDFBFBFD000100FD037FF9 41 - ASCII for “A” 32 - ASCII for “2” 0090- Sz - size is 144 bytes 0005 - ID - ID is 0005 0001 - Ver - Version is 1 00 - Vib # is 0 00000000 - Shot ID is 0 00000000 - EpId is 0 FE0001... 0100FD - Correlation data 2’s complement; 128 samples

037F - Gain word applied to all correlation samples. The actual gain is 895/32768, which equals 0.027313232421875.

F9 - ChkSum - XOR check sum. Revision Response Message - Id = 0006:

A2 Sz(2) Id(2) Version(2) Revision(2) ChkSum(1)

This message returns the revision level software/firmware in use by the Pelton System. The Version field is specious in that the Recording System must be prepared to accept this message whatever the value in the Version field. The system cannot know the version level of each message until after the Revision Request message has been sent and the Revision Request message is received. The Version field is included here for consistency. This message should be formulated and sent immediately upon receipt of the Revision Request Message as the Recording System requires this message to properly initialize the messaging system. This document reflects Revision level 2. Example Message ID=0006 Version=1 4132000700060001020104 41 - ASCII for “A” 32 - ASCII for “2” 0007 - Sz - size is 7 bytes 0006 - ID - ID is 0006 0001 - Ver - Version is 1 0201 - Rev - Major Revision is 2 release number is 1 04- ChkSum - XOR check sum of ID, Ver, & Revision =04 hex




Abort Response Message - Id = 0007: Not Used. Message - Id = 0008: Not Used. SHOTPRO PSS Information Message - Id = 0009:

A2 Sz(2) Id(2) Version(2) ShotPro#(1) CTB(2) FirstPick(2) FireLineResist(2) GeophoneResist(2) Status(1) ChkSum(1) The Shot Pro data will be sent after each shot. The ShotPro# field identifies the current ShotPro by number, range : 0 - 15. The CTB field contains Confirmed Time Break data in microseconds. The FirstPick field contains Up-hole Geophone Pick Time data in 500 µsec per step. If the unscaled value is < 1 or > 500, then the First Pick value is invalid. The FireLineResistance and GeophoneResistance fields contains results of measurements, status of the results, and scaling information for the resistance values. The Status field contains status and scaling information for the resistance values. Resistance Status Bits: These bits are the least significant 5 bits of both resistance fields. Bits 0, 1 are the scaling values, bit 2 is Range checking, bit 3 is Limits checking. Bit 4 of the Geophone resistance field is the battery status bit. Scaling bits: Value Calculation 0 No scale, leave value as is. 1 Resistance = ((Raw Value - 2176) * 5120 + 128) / 256000 2 Resistance = ((Raw Value - 2056) * 5106 + 128) / 25600 3 Resistance = ((Raw Value - 2048) * 5172 + 128) / 2560 Range bit: 0 Value is in range

1 Value is out of range Limits bit: 0 Value is out of limits

1 Value is in limits Battery bit: 0 Battery is ok.

1 Battery is low. The bits in the Status field contains data that is related to the scaling of the geophone voltage information, whether or not it is clipped, and if this PFS is being retransmitted. Bit 4 (from 0) indicates if the geophone signal is clipped or not. 0 = Not Clipped, and 1 = Clipped. Bit 2 indicates if the PFS is retransmitted or not. 0 = Normal PFS, 1 = Retransmitted PFS. The signal data is not sent to the recording system. From the original Shot Pro, Bit 3 is always 0. From the Shot Pro II, if bit 3 = 1, then .25 mSec is added to the First Pick time.

Example Message ID=0009 Version=1 4132000F000900010100C8001C00320BB8015D 41 - ASCII for “A” 32 - ASCII for “2” 000F - Sz - size is 15 bytes 0009 - ID - ID is 0009 0001 - Ver - Version is 1 01 - Shot Pro # is 1 00C8 - CTB is 200 microseconds 001C - First Pick is 14 milliseconds 0032 - Fire Line Resistance – calculates to invalid value. In Range, out of

Limits. 0BB8 - Geophone Resistance – calculates to 187 ohms. In Range, in Limits. 01 - Status is 01. Bit 4 = 0, so Geophone signal is not clipped. 5D- ChkSum - XOR check sum of ID, Ver, ShotPro#, CTB, FP, Res& Status =5D hex

Document History: 09/25/2002 KSR Document started. 10/16/2002 KSR Added note regarding the retransmission of missing PSS messages. 12/08/2003 KSR Added further status information for Shot Pro PFS message, which




includes a change for Shot Pro II

Air Gun Page 14.1.1



Air Gun Mode

Air Gun Mode is currently under revision and will be released at a later date, upon completion.

Air Gun Page 14.1.2




Uphole Page 15.1.1



UPHOLE SIMULATOR-2

General Description:

The Pelton Uphole Simulator-2 is designed to receive a firing signal from a Pelton Shot Pro or SPII unit, which are designed to detonate explosive devices, and to produce a signal similar to the signal that could be produced by a geophone placed at the top of the shot hole. The CAP wires of the simulator should be connected to the firing line of the detonator unit. This connection may be made without regard to polarity. The UPHOLE cable should be connected to the detonator where the uphole geophone would normally be connected. The polarity of this connection will determine whether the first break of the uphole signal is positive or negative. The geophone signal from the simulator is a fading sinusoidal wave (starting with a selectable amplitude, with the amplitude decreasing quickly). The level and timing of the uphole signal wave are controllable by switches on the front panel of the simulator. The simulator will also respond to Time Break signals from encoders and decoders. LED indicators will show whether Time Break signal from the unit connected to the ENCODER input occurs at the same time as, or earlier, or later than the Time Break signal from the unit connected to the DECODER input or the CAP wires of the simulator. The unit will also output serial text messages indicating the timing relationship between the ENCODER and DECODER inputs or the ENCODER and CAP inputs. Specifications: • Power: Internal 9 Volt battery • Cap Input: 10 to 600 Volts, 4 amps minimum required to trigger a

response. • ENCODER and DECODER: inputs +2V to +20v • UPHOLE Output: 0.2, 2, or 4 Volt fading sinusoidal signal, • Delay of UPHOLE output pulse after CAP input signal: 10, 20, or 40

mSec • Dimensions: 3” X 6” X 2.25” (76mm X 55mm X 152mm) excluding cables • Weight: 1.2 lb. (.54 Kg) including battery and cables • Timing resolution: 1 microsecond • Serial text messages are sent and received via an RS232 connection,

at 19,200 Baud, 8 data bits, No Parity, 1 stop bit. • A null modem cable should be used to connect the simulator to a

computer.

Uphole Page 15.1.2



Operation: Testing start time accuracy using Time Break from an encoder and the firing line signal from the HIGH VOLTAGE terminals of a SPII Decoder or similar device:

1. Press the “ON” button on the simulator and hold it down for at least 2 seconds to turn the simulator ON. The LED by the ON button should stay on when power is on.

2. Press the TEST switch and observe the >> LED flashing for a few seconds.

3. Connect the CAP wires of the simulator to the firing line of the detonator. The Polarity of this connection is not critical.

4. Connect the UPHOLE wires of the simulator to the uphole geophone input of the detonator. The polarity of this connection will determine whether the first break of the uphole signal is positive or negative.

5. Connect the Time Break signal from the encoder to the ENCODER BNC connector on the simulator.

6. Set the DELAY switch for 10, 20, or 40 mSec.

7. Set the OUTPUT switch for 0.2, 2, or 4 Volts.

8. Make the encoder cause the decoder to fire a shot. The microprocessor in the simulator detects the polarities of the input signals during the first shot.

9. Make the encoder cause the decoder to fire another shot. The timing indications should be valid after the second shot.

10. When the detonator box fires, the simulator will do the following:

a. Wait for an amount of time determined by the DELAY switch.

b. Output a sinusoidal signal, the amplitude controlled by the OUTPUT switch.

c. One of the 3 LED’s above the words “T.B. ADJ.” will illuminate for a few seconds when the uphole signal is issued. See the Explanation of Indications section, below.

d. A text message will be issued via the 9 pin D connector, indicating the timing relationship of the ENCODER and the DECODER after the uphole signal has been issued.

e. The simulator will be ready for another test after the timing indicator LED goes out or stops flashing.

11. If desired - Conduct continuity tests on the blasting unit for the firing line and the uphole line. The results, when connected to the Uphole Simulator-2, should be 1 Ohm for the firing line and 1,000 Ohms for the uphole line.

12. The unit will automatically turn it’s self off after about 5 minutes of inactivity.

Uphole Page 15.1.3



Testing the functionality of a Shot Pro Decoder without using the time break signal from an Encoder:

1. Press the ON button on the simulator and hold it down for at least 2 seconds to turn the simulator “ON”. The LED by the ON button should stay on when power is on.

2. Press the TEST switch and observe the >> LED flashing for a few seconds.

3. Connect the CAP wires of the simulator to the firing line of the detonator. The Polarity of this connection is not critical.

4. Connect the UPHOLE wires of the simulator to the uphole geophone input of the detonator. The polarity of this connection will determine whether the first break of the uphole signal is positive or negative.

5. Power up the decoder.

6. Conduct continuity tests on the blasting unit for the firing line and the uphole line. The results, when connected to the Uphole Simupator-2, should be 1 Ohm for the firing line and 1,000 Ohms for the uphole line.

7. Set the DELAY switch for 10, 20, or 40 mSec.

8. Set the OUTPUT switch for 0.2, 2, or 4 Volts.

9. Charge and Arm the decoder.

10. Make the encoder cause the decoder to fire a shot.

11. When the detonator box fires, the simulator will do the following:

a. Wait for an amount of time determined by the DELAY switch.

b. Output a sinusoidal signal, the amplitude controlled by the OUTPUT switch.

c. The >> LED will flash for a few seconds.

d. The simulator will be ready for another test after the timing indicator LED goes out or stops flashing.

12. The proper uphole signature should be shown on the SPII’s display 13. If enabled, the PFS data should be transmitted from the decoder and should appear on the appropriate equipment in the recorder.

14. The unit will automatically turn itself off after about 5 minutes of inactivity. It may also be turned off by using a computer to send the simulator a “turn off” message via the 9 pin connector.

Uphole Page 15.1.4



Testing start time accuracy using Time Break signals from two units: Note: The two units can be an encoder and a decoder, two decoders, a master encoder and a slave encoder, etc. The source of the time break signals from both units should be similar, e.g. if two Vib Pros are used, the Time Break should come from JE or J1 on both units, not from JE on one unit and J1 on the other. 1. Press the “ON” button on the simulator and hold it down for at least 2 seconds to turn the simulator ON. The LED by the ON button should stay on when power is on. 2. Press the TEST switch and observe the >> LED for a few brief flashes. 3. Connect Time Break signals from the encoder and the second unit to the ENCODER and the DECODER BNC connectors on the simulator. 4. Make the encoder cause the decoder(s) or slave encoder to start a sweep or fire a shot. The microprocessor in the simulator detects the polarities of the input signals during the first shot. 5. Make the encoder cause the decoder(s) or slave encoder to start a sweep or fire another shot. The timing indications should be valid after the second start. 6. When the detonator box fires, the simulator will do the following:

a. Wait for an amount of time determined by the DELAY switch. b. Output a sinusoidal signal, the amplitude controlled by the OUTPUT switch. c. One of the 3 LED’s above the words “T.B. ADJ.” will flash when the uphole signal is issued. d. A text message will be issued via the 9 pin D connector, indicating the timing relationship of Time Break signals connected to the ENCODER and the DECODER BNC connectors, after the uphole signal has been issued. e. The simulator will be ready for another test after the timing indicator LED goes out or stops flashing.

7. The unit will automatically turn itself off after about 5 minutes of inactivity. It may also be turned off by using a computer to send the simulator a “turn off” message via the 9 pin connector.

Uphole Page 15.1.5



Explanation of Indications:

Serial text messages:

A typical message when comparing Time Break from 2 units is: Time Break is Good Encoder needs 00000 microseconds of more time Decoder -__-.pulse Encoder _--_.pulse…..

A typical message when comparing Time Break from an Encoder to the high voltage signal from a Decoder is: Time Break is Good Encoder needs 00000 microseconds of more time Decoder fire pulse Encoder _--_.pulse…..

1. Pelton’s Serhex32.exe and general terminal emulation programs can be used to receive and send messages.

2. Timing errors of less than 5 microseconds result in a message indicating zero error.

3. Messages saying the encoder needs more time indicate Time Break from the encoder is occurring 5 or more microseconds before the event from the decoder. A larger value needs to be used for Encoder Delay.

4. Messages saying the encoder needs less time indicate Time Break from the encoder is occurring 5 or more microseconds after the event from the decoder. A smaller value needs to be used for Encoder Delay

5. The last two sections of the message show whether the simulator detected that the input signals were active high or active low. A message showing -__- indicates the input signal was normally high and goes low at time break. A message showing _--_ indicates the input signal was normally low and goes high at time break. As shown above, when comparing Time Break from an Encoder to the high voltage signal from a Decoder, the Decoder section of the message will show the word fire instead of showing the polarity of the high voltage signal.

LED Indications:

There are three timing indicator LED’s. They are labeled << IN RANGE and >>.

1. A steady << light indicates the encoder is starting 10 or more microseconds after the decoder.

2. A steady >> light indicates the encoder is starting 20 or more microseconds before the decoder.

3. A steady IN RANGE light indicates the encoder is starting at the same time the decoder is, -20 to +10 microseconds.

4. The >> LED flashes several times if a decoder time break was detected but none was detected for the encoder. The >> LED will also flash several times if the TEST button is pressed with the unit powered up.

5. The << LED flashes several times if an encoder time break was detected but none was detected for the decoder.

6. The LED beside the ON button is the power on indicator. It will be on any time the simulator is on.

Uphole Page 15.1.6



Troubleshooting: Battery Life: The battery life is usually quite long. Low battery will cause one or more of the following indications: 1. Wrong delay between shot and uphole signal 2. Dim LED indications 3. Low uphole signal amplitude 4. Erratic text messages Uphole Signal: The amplitude of the uphole signal will be affected by the load the detonator presents to the uphole signal line. The voltages listed around the VOLTS switch are accurate if the load is about 2000 Ohms. Firing Current: The firing signal must be greater than 4 Amps for the simulator to respond.

Safety Page 16.1.1



SAFETY

The following Safety Guidelines were published in the Seventh Edition of the IAGC Land Geophysical Operation Safety Manual. The IAGC Safety Manual has been prepared and compiled through the best efforts of the IAGC staff and others. However, IAGC or Pelton Co. does not represent that this is entirely comprehensive, accurate or covers each and every safety topic or risk which may be encountered by those using this manual and the IAGC and Pelton Co. disclaims all responsibility and liability for any such utilization of this information by the users thereof. By receipt of the Shot Pro II Manual, the recipient/user agrees to release, indemnify and defend the IAGC and Pelton Co. from and against any and all claims, demands and liabilities which may arise from the utilization of the manual by such recipients/ users. LAND SURFACE SHOOTING

1. Before any surface shooting begins, a plan will be made and approved by management and client detailing --

A. Type and amount of explosive used, including fire retardant characteristics.

B. A pattern diagram.

C. The method of operation.

D. Safety requirements including sympathetic detonation prevention.

E. Aircraft operations.

2. Procedures to ensure the safety of employees, the public, livestock, wildlife and property shall be established prior to any implementation of surface shooting techniques using explosives.

3. Explosives shall be transported and handled according to prevailing regulations.

4. Detonators shall be transported and handled in compliance with local regulations.

5. Employees working in the shot area shall be provided with approved hearing protection devices, and shall wear them at the time of the detonation shot.

6. Employees working in the shot area shall wear hard hats. 7. Employees shall be thoroughly instructed in the hazards that exist

in surface shooting techniques, and a warning system shall be established.

Safety Page 16.1.2



8. Shooter and shooter's helpers should be aware of overhead fallout from trees, cliffs, or rocks resulting from the shot. Stay up slope of the shot point in case there is landslide and loosened rocks.

9. The supervisor shall monitor and enforce the use of personal protective equipment provided to the employees.

10. Prior to actual layout of explosives, each employee shall be assigned a specific duty to perform, and instructed to adhere to the planned procedure. Should that procedure be altered in any manner, the employee in charge of the layout operation shall be notified of that change, and all members of the layout crew shall be made aware of that change. Additional instructions shall be given at this time to alleviate any chance the altered procedure might pose additional hazards.

11. Only qualified persons (shooters and helpers) designated by the person in charge shall prime explosives, and then only when instructed by that supervisor.

12. Minimum distances shall be maintained between persons handling explosives or exposed charges and any transmitter.

13. The shooter shall have complete control of the shot detonation. He can, at any time, abort the shot due to any abnormality at the shot location.

14. Communications between the shooter, explosives crew, and all other members of the crew shall be established prior to detonation in order to eliminate any chance of anyone entering the shot area. All crew members should report the presence of any non-crew members seen in the operation area.

15. In the event the shot pattern is located in such a configuration that the entire pattern is not visible to the shooter, guards, or observers shall be positioned in such a manner as to be visible to the shooter and -- at the same time -- to have clear visibility of the shot area. If the area is located in such a way as to make this impossible, audible communication shall be established, either by radio or prearranged signals, as to the conditions of the shot area between the guards or observers and the shooter. The shot shall not be detonated until the shooter is completely satisfied the area is secured.

16. An audible signal -- or sufficient audible level to be heard within the area of the shot pattern, shall be sounded prior to each shot time.

17. No employee shall enter the shot area after detonation until the shooter or employee in charge gives permission to do so.

18. Warning signs shall be posted on all roads and trails that lead to the shot area. The signs will denote the use of explosives in that area. Use the local language on all signs and placards.

Safety Page 16.1.3



19. All permit stipulations concerning crew conduct and clean-up operations shall be strictly followed and enforced.

General Provisions

Do not store, handle, transport, or use explosives or blasting agents when there is an undue hazard to life and/or property.

1. Do not handle, transport, or use explosives while under the influence of any disabling drug, alcohol, illness, or infirmity.

2. Only qualified and authorized persons shall handle and use explosives.

3. All persons handling explosives or working around explosives must read and become familiar with the manufacturer's "dos and don'ts" usually packaged in every case of explosives and electric blasting caps (detonators).

4. Explosive handlers should be individually certified for a pre-defined period. They should confirm and sign in writing that they have understood all explosives handling procedures.

All explosives must be accounted for at all times!!!

1. The employer must maintain an Inventory and Use record of all explosives, according to local regulations.

2. Any knowledge of theft or loss of explosive materials must be reported to the supervisor who, in turn, must promptly notify the corresponding local and national authority.

3. Explosives must be stored in an approved magazine.

4. Do not leave stored explosives unattended, except when in a magazine approved for unattended storage.

5. All loaded shot holes must be attended or protected. A protected hole is one that has been loaded so that the charge cannot be removed. A charge must be secured in the hole by anchors, stemming, or tamping. The detonator leads should be inaccessible to, or concealed from unauthorized persons.

6. Never sell or deliver explosives to any unauthorized person.

7. Empty boxes, paper, and fiber packing materials that have contained explosives shall not be used again for any purpose, and shall be destroyed according to the recommendations of the manufacturer.

8. Only use tools, machines, equipment, materials, and devices, procedures or techniques that are approved for the job. Approved means that the device or method has been designed, manufactured and implemented by competent persons familiar with the type of work, or have been adopted by a consensus of the industry.

Safety Page 16.1.4



9. All tools, machines, equipment, or devises used with explosives shall be kept in good condition, and be checked or tested periodically to ensure that they function properly, and in accordance with the manufacturer's recommendations.

10. Use older stocks of explosives first. Explosives that have been

deteriorated must be destroyed according to recommendations of the manufacturer.

11. A plan for the means of escape from the vicinity of explosives must

be provided for employees at all times.

12. Do not detonate explosives in congested areas or in close proximity to any structure, railroad, highway, power line, pier communication line, dock vessel, or other installation that may be damaged.

13. Do not fight a fire that is in imminent danger of contact with

explosives. Move all employees to a safe area, and guard the fire area against intruders.

14. Insofar as possible, vehicles and motorized equipment should have

exhaust systems designed to provide minimum fire hazards when used in the vicinity of explosives. Smoking, firearms, matches, open flame lamps, and other flame or heat producing devises and sparks are prohibited in or near any explosive magazine or while explosives are being handled, transported, or used.

The prohibition against firearms does not apply when they are required to protect the health and life of employees and security of the explosives, providing they are approved by management.

15. Take the following precautions to prevent accidental discharge of

electric detonators from current induced by galvanic currents, radio transmitters, electrical fences, lighting, adjacent power lines, dust, or sand storms, snowstorms or other sources. Extremely high static conditions exist in snow or blowing snow. The same conditions are present during sand storms. Suspend all explosive operations during these high static conditions. Disconnect recording cables to prevent possible damage. Be aware of possible electrical shock when touching any grounded metal object.

A. Use static-resistant detonators that are shunted at all times,

except when being tested or when ready to fire.

B. Use only approved blaster's galvanometers or other instruments designed for testing electric detonator circuits.

C. Do not use multimeters or circuit testers to test detonators.

D. Comply with recommendations concerning shooting in the vicinity

of radio transmitters, as shown on the following chart.

Safety Page 16.1.5



Minimum Approved Distances Between Point Of Handling Or Exposed Electric Caps and Transmitters

Used In Seismic Field Operations

Distance Power (Meters) (Feet)

(W) 25 MHz 150 MHz 25 MHz 150 MHz 0 - 5 21 5.8 70 20 5 - 10 30 9 100 30 10 - 50 75 21 250 70 50 - 100 105 30 350 100 100 - 250 150 47 500 160

Note: For other transmitters -- such as commercial, military, or other private types (TV, microwave, etc.) - identify the type of transmitter, power, and frequency, and contact detonator manufacturer or explosive supplier for guidelines or offsets.

E. Post warning signs against the use of mobile radio transmitters on all roads within 100 m (350 ft) of the loading and shooting operations. Signs must have 10-cm (4 in.) white letters with 1.4 -cm (5/8-in.) stroke on a red background with words. "Explosives in Use -- Turn Off Transmitters," or the equivalent in the local language.

F. Do not use tools, equipment, or material that may cause

dangerous electrical currents by galvanic action or sparks in a shot hole.

G. Handle and use explosives only during the hours from one-half

hour before sunrise to one-half hour after sunset. If explosives must be handled or used at night, provide and use adequate light.

Safety Page 16.1.6



STORAGE For this subsection, "storage" means storing explosives and blasting agents in storage facilities under the control of the user. Consult local authority for safe distances to explosive storage. 1. Store explosive materials in approved facilities as authorized by

the agency having jurisdiction in the country of operations. 2. Do not store damaged explosives with other explosives, or store

explosives with a detonator inserted. Contact the supplier to dispose of damaged explosives. Damaged explosives should be safely destroyed.

3. Primers and boosters can be stored with other explosives, but must

not be stored with detonators. 4. Magazines and use of explosives must be in charge of a competent

person who must enforce all safety precautions. This same person should be in charge of inventory.

5. Use non-mass detonating cap where available. 6. Keep the area around a magazine clear of any combustible material

for at least 15 m (50 ft.). TRANSPORTATION (Not including Aircraft) For this subsection "transportation" means only the transportation of explosives between the user's storage facility and the work location, and between work locations. Use the local language on all placards. 1. Do not smoke, carry matches, flame-producing devices, firearms, or

loaded cartridges while in or near a vehicle carrying explosives. This prohibition against firearms does not apply when they are required to protect the health and life of employees or the security of the explosives and have been approved by management.

2. Vehicles or conveyances transporting explosives shall only be driven

by, and be in the charge of, a licensed driver who is physically fit. He must be familiar with regulations governing the transportation of explosives in the country or area of operations.

3. Do not carry or transport explosives in, upon a public conveyance, or a vehicle carrying passengers for hire.

Safety Page 16.1.7



4. Vehicles used for transporting explosives must be strong enough to carry the load without difficulty, be in good mechanical condition, and periodically inspected.

5. Electric detonators can be transported on the same vehicle with

other explosives, provided they are segregated and carried in an approved detonator container.

6. Explosives can be transported on vehicles carrying equipment (i.e.,

drills) or materials (i.e., water), provided that the explosives are carried only in approved magazines securely mounted on the vehicle, and that while on public roads, the magazine and separate detonator box are closed and locked.

7. Explosives can be transferred from one vehicle to another within the

project area without notifying authorities, provide that the transfer is made under qualified supervision, and not in a congested area or near a public road, inhabited building, operating equipment, or any kind of loading or shooting operation.

8. When explosives are transported by a vehicle with an open body, they

must be in the original manufacturer's containers, protected against sparks and moisture with a fire resistant tarpaulin, and lashed securely in or on the conveyance.

9. Every vehicle or conveyance used for transporting explosives must be

marked or have placards on both sides, the front, and the rear. The placards must signify the class of explosives being transported, unless local government regulations require alternate identification procedures.

10. Each vehicle used for transporting explosives must be equipped with

two fully charged fire extinguisher in good condition. The driver must be trained in the use of the extinguisher on his vehicle. The vehicle should also include a first-aid kit, tool kit etc.

11. In the event of breakdown or collision, the local fire and police

departments must be promptly notified. Explosives should be transferred from the disabled vehicle to another only when qualified supervision is provided.

12. Vehicles or conveyances containing explosives, blasting agents, or

blasting supplies must not be taken inside a garage or shop for repairs or servicing.

13. Vehicles transporting explosives shall avoid congested areas and

heavy traffic. Routes for hazardous materials through congested areas that have been designated by local authorities shall be followed.

Safety Page 16.1.8



14. Do not leave any vehicle transporting explosives unattended. 15. Explosives or blasting agents not in original containers must be

placed in a suitable container when they are transported manually or by pack animal.

16. Detonators and other explosives must be carried in separate

containers when they are transported manually or by pack animal. 17. Do not transport explosives manually or with pack animals during

sand or snow storms, or any time where there is a high static electricity condition.

USE OF EXPLOSIVES For this subsection, "use" means handling, loading, and detonating explosives to create elastic waves within the earth. Explosives must not be used for any other purpose. Procedures that ensure safe handling and storage of explosives at the work area must be established before explosives are transported to work area. If in doubt, contact your supplier before receiving explosives. 1. While at the work area, explosives that are not being used must be

kept in a magazine or in suitable containers. The magazines must be kept closed, and the doors or lids secured and locked except when explosives are being removed or replaced. Locks and lock covers should be of sufficient quality to ensure the security of the explosives.

2. There must be no smoking, fire, or open flame within 15 m (50 ft.)

of any explosive. 3. Any fire or open flame within 50 m (150 ft.) of any explosive shall

not be upwind from the explosive. 4. Shooters and shooters' helpers should wear appropriate protective

devices such as hard hats, ear and eye protection.

Safety Page 16.1.9



Procedures that ensure safe handling, preparation, and loading of explosive charges shall be established before loading is started.

1. No equipment, persons, or activity other than that required for loading holes with explosives shall be near the hole. All persons in the vicinity of the hole shall be able to hear, see, or otherwise be aware of any order, warning, or hazardous situation. When loading a pattern of holes with more than one loading crew, the crews shall be separated by distances consistent with safe operation and supervision of crews.

2. Explosives other than the charge being loaded must not be closer that 3 m (10 ft) of a loaded hole or 8 m (25 ft) of a hole being loaded, except when explosives are carried in a ready box on the drilling unit that is used in the loading process. Use special precautions if explosives other than the charge being loaded are closer than 8 m (25 ft) of a hole being loaded.

3. All holes shall be sufficiently large so that the explosive cartridge can be easily inserted.

A. The loader shall check the hole before loading in order to ensure that it is open to a safe depth.

B. Load holes immediately after drilling, if possible.

4. Only the explosives required to make up one charge should be removed from the ready box or supply.

A. Do not make up or detonate charges in advance.

B. Load a charge immediately after it is made up. 5. Do not prime the charge until it is at the hole and is ready to

load. 6. Priming must be in accordance with the manufacturer's

recommendations, and may vary from one explosive product to another.

A. Insert detonators in holes provided by the manufacturer or in holes made with a suitable tool of non-sparking material.

B. Primes charges as near to the top of the charge as is safe.

C. After the detonator has been inserted in the charge, place two

half-hitches of the detonator leads around the charge in order to prevent strain on the detonator.

D. When a charge is made up of more than one cartridge, load the primed stick last or at the top. When the charge is loaded in the hole, and before any stemming (hole plugging) is done, check the circuit with an approved blaster's galvanometer. Stand clear of the hole while testing.

Safety Page 16.1.10



7. Unfold or unspool the detonator leads only as necessary in order to lower the primed charge. Never toss or throw a detonator in the air, or extend them along the ground until the charge is in place.

8. Loading poles shall be of wood or other non-conducting material that

does not collect static electricity. Connectors, stingers, spoons, and any other metal parts shall be non-sparking.

9. No sparking material shall be exposed on any part of the mechanical

loading device that may come in contact with the explosive. 10. When lowering the charge, avoid excessive strain, kinking, or

abrasion of the detonator lead wires. When necessary, use rope or other non-conductive cord to lower a heavy charge.

11. When using loading poles or tools, use only steady pressure to

overcome the buoyancy of the charge. The charge shall never be jarred or struck with loading poles or tools.

12. When weights are used to decrease the buoyancy of a charge, they

shall be non-sparking material or fastened to the charge with a non-conductive material.

13. After a primed charge has been loaded, do not try to retrieve it

unless detonating or abandoning it would create an undue hazard. Use extreme caution when retrieving a primed charge. As soon as the charge is withdrawn, carefully remove the detonator.

14. Use suitable means, such as charge anchors or stemming, to ensure

the charge does not float. To determine that the charge is at the proper depth, gently pull the detonator leads until the weight of the charge is felt, measure and subtract the remaining detonator lead from the total detonator lead length usually noted on the spool.

15. Employees must be instructed in the proper procedure for plugging

shot holes after loading.

A. Use only inert substances for the stemming material.

B. When the stemming material is to be compacted with a non-sparking loading pole, place at least 60 cm (2 ft) of the material above the charge before using the loading poles.

Safety Page 16.1.11



16. Before detonating any explosive, ensure the safety of employees, the public, livestock, wildlife, and the property.

A. The shooter must be in control of the shot point area and

stationed a safe distance before initiation of the shot. The shooter must know the size and depth of the charge, how the shot hole is tamped or plugged, proximity to power lines or any other structures or installation, and the presence of any persons in the vicinity of the shot point.

B. The shooter at this station must have an unobstructed view of

the shot point area, or should station spotters about the area to signal when the area is clear.

C. The shooter must determine the time of the shot, but the shot

instant may be provided remotely from the recording instruments. If a remote devise is used, the blasting machine shall have at least one "dead man" type switch that the shooter must close in order to complete the circuit.

D. The firing line must be shunted before detonator leads are

connected, and must be kept shunted until connected to the blasting machine.

E. The connections must be carefully made, and all wires well

insulated and in good condition. Pattern holes must use a series circuit firing line.

F. Blasting machines must be capable of delivering current in

excess of that required to fire all the detonators in the circuit. Use only series circuits. All detonators used in any single shot must be of the same function and manufacturer. Do not mix unlike detonators.

G. Test the blasting machines periodically using procedures

recommended by the manufacturer in order to determine that they are capable of delivering power at the rated capacity.

H. Before a shot is fired, a loud warning signal shall be given by

the person in charge, who has made certain that all surface explosives are in a safe location, all persons and conveyances are at a safe distance or under sufficient cover.

I. If there are any misfires, it is recommended that all persons

stay away from the charge for at least one half hour. It is not recommended to reprime a loaded hole, except in supervised circumstances.

Safety Page 16.1.12



J. Whenever the detonator leads or firing line might be thrown over a power line by the force of an explosion, ensure that the total length of wires is kept too short to hit the lines, and that the wires are securely anchored to the ground at the shot hole.

K. A shot hole should not be drilled closer than two times the

projected hole depth from a power line unless precautions are taken for hole blow. If a firing line wire is thrown on to a power line, post a guard and call the power company to remedy the situation. Do not touch the blasting machine.

L. When a cased hole is shot, take special precautions to ensure

against possible injury from casing being ejected from the shot hole.

M. Shooters and shooter's helpers should remain upwind and avoid

breathing smoke, fumes, and dust from the shot. These may cause severe headaches and nausea.

N. Always beware of possible delayed blowouts up to five minutes after the initial shot.

O. Never use more than one firing line in order to avoid connecting to the wrong firing line and detonating a different charge than the one intended.

P. Shooter should check detonator lead and observe the amount of lead exposed. Occasionally, a charge will be pulled toward surface or float if not properly tamped or loaded.

DOCUMENTATION Page 1


04Dec03 C:\V6MAN\SHOTPRO\SPDOC.DOC

SHOT PRO II DOCUMENTATION SHOT PRO II ENCODER SYSTEM BOM 105-000030M 1.1 RADIO VHF 25W RADIO WITH HARDWARE BOM 014-000001 2.1

RADIO 1/2 WAVE ANT W/ACC HIGH BAND BOM 017-000052 2.3 ENCODE CABLE ASSEMBLY SCHEM 101-100150 3.1a SHOT PRO II UNIT BOM 101-100163M 4.1

ENCLOSURE ASSEMBLY BOM 101-100152M 5.1a FRONT PANEL ASSEMBLY BOM 101-100164M 6.1 SHOT PRO II CARD-1 SCHEM 101-100908 7.1a STANDARD GPS CARD SCHEM 101-100933 8.1a

ENCODER MOUNTING BRKT BOM 101-100940 9.1

DECODER SYSTEM BOM 105-000031M 1.2 VHF 25W RADIO SP DECODER W/HARDWARE BOM 014-000011 2.2

1/2 WAVE ANT W/ACC HIGH BAND BOM 017-000052 2.3 DECODE CABLE ASSEMBLY SCHEM 101-100151 3.2a SHOT PRO II UNIT BOM 101-100163M 4.1

ENCLOSURE ASSEMBLY BOM 101-100152M 5.1a FRONT PANEL ASSEMBLY BOM 101-100164M 6.1 SHOT PRO II CARD-1 SCHEM 101-100908 7.1a STANDARD GPS CARD SCHEM 101-100933 8.1a

BACKPACK ASSEMBLY BOM 101-100922 10.1

CARDS SHOT PRO II CARD-1 SCHEM 101-100908 7.1a H8S CARD SCHEM 001-600079 7.2a FIRING LINE CARD-1 SCHEM 101-100161 5.1f

CABLES ENCODE CABLE SCHEM 101-100150 3.1a DECODE CABLE SCHEM 101-100151 3.2a RADIO PIGTAIL CABLE SCHEM 101-100226 3.2c

SHOT PRO II OPTIONS SUB-METER GPS BOM 101-100923 11.1a UPHOLE SIMULATOR UNIT BOM 101-100088M 12.1a HARDWARE SPARES BOM 102-000134 13.1 SHOT PRO II ENCODE CABLE WITH JE CONN SCHEM 101-100977 14.1a RTI Y CABLE SCHEM 101-100978 14.2a

Pelton Company, Inc.An Input/Output Inc. Company

105-000030MRevision: 000

SHOT PRO II ENCODE SYSTEM

Bill of Materials:

Part Number Qty/Bill U/M Description Ref Designator

1.00014-000001 EACH VHF 25W RADIO WITH HARDWARE1.00022-000058 EACH SHOT PRO II MANUAL1.00025-000003 EACH PELTON SOFTWARE CD & CASE1.00101-100150 EACH SHOT PRO II ENCODE CABLE1.00101-100163 EACH SHOT PRO II UNIT1.00101-100226 EACH CBL RADIO INTERCONNECT N/CONN1.00101-100940 EACH SHOT PRO II ENCODER MNT BRKT

12/4/2003Print Date: Page: 112:19:28PM Drawn By: MRG Approved By:

mgray

Page 1.1


105-000031MRevision: 000

SHOT PRO II DECODE SYSTEM

Bill of Materials:


1.00014-000011 EACH VHF 25W RADIO SP DECODER3.00016-000034 EACH 12V BATTERY WITH CONNECTOR1.00017-000031 EACH 12V BATT CHARGER W/CON1.00101-100151 EACH SHOT PRO II DECODE CABLE1.00101-100163 EACH SHOT PRO II UNIT1.00101-100226 EACH CBL RADIO INTERCONNECT N/CONN1.00101-100922 EACH SHOT PRO II BACKPACK ASSEMBLY


mgray

Page 1.2


014-000001Revision: 000

VHF 25W RADIO WITH HARDWARE

Bill of Materials:


1.00014-000006 EACH VHF 25 WATT RADIO1.00017-000052 EACH 1/2 WAVE ANT W/ACC WIDE BAND1.00101-100800 EACH 25 FOOT RG58 ANTENNA CABLE


mgray

Page 2.1


014-000011Revision: 000

VHF 25W RADIO SP DECODER

Bill of Materials:


1.00014-000006 EACH VHF 25 WATT RADIO1.00017-000052 EACH 1/2 WAVE ANT W/ACC WIDE BAND1.00101-100916 EACH CABLE 3 FOOT RG58 W/CONN


mgray

Page 2.2


017-000052Revision: 000

1/2 WAVE ANT W/ACC WIDE BAND

Bill of Materials:


1.00012-300058 EACH HXA4 ANTENNA CONNECTOR1.00012-300060 EACH BA ANTENNA1.00017-000043 EACH NMOWB150C 138-174 MHz ANTENNA1.00017-000080 EACH W540 54IN WHIP ANTENNA1.00019-000680 EACH ANTENNA SPRING


mgray

Page 2.3

mgray

Page 3.1a


101-100150Revision: 000

SHOT PRO II ENCODE CABLE ASSY

Bill of Materials:


1.00012-200050 EACH MS3106E-14S-5S CONN 5S CABLE2.00012-200098 EACH 720-8034 CONN 9S D1.00012-200110 EACH MS3420-6 CONN .312 BOOT2.00012-200111 EACH MS3420-4 CONN SMALL BOOT1.00012-200141 EACH MS3116F16-26S CABLE CONN 26S2.00012-300029 EACH 510-2400 CONN 9 DIN CLAMP

12.00013-000018 FOOT 8523 WIRE 20GA BLACK INSULATED12.00013-000023 FOOT 8523 WIRE 20GA RED INSULATED48.00013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED12.00013-000030 FOOT 8524 WIRE 22GA GREEN INSULATED36.00013-000031 FOOT 8524 WIRE 22GA GRAY INSULATED12.00013-000033 FOOT 8524 WIRE 22GA RED INSULATED36.00013-000035 FOOT 8524 WIRE 22GA WHITE INSULATED12.00013-000036 FOOT 8524 WIRE 22GA YELLOW INSULATD48.00013-100004 FOOT 2254/2 CBL 2 WIRE SHIELDED12.00013-100022 FOOT 2254/1 CBL 1 WIRE #22 SHIELDED12.00013-300001 FOOT 1/2 BLACK EXPANDO SHEATHING60.00013-300002 FOOT 1/4 BLACK EXPANDO SHEATHING

2.00015-000022 EACH ATC-7 1/2 AMP BLADE FUSE2.00015-000025 EACH HHG FUSE HOLDER INLINE BLADE1.25103-000010 FOOT 1/16 SHRINK TUBING0.50103-000012 FOOT 1/4 SHRINK TUBING1.25103-000013 FOOT 1/8 SHRINK TUBING0.50103-000014 FOOT 3/16 SHRINK TUBING0.50103-000015 FOOT 3/16 SHRINK TUBING RED0.25103-000017 FOOT 3/4 SHRINK TUBING


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Page 3.1b

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Page 3.2a


101-100151Revision: 000

SHOT PRO II DECODE CABLE ASSY

Bill of Materials:


1.00012-200050 EACH MS3106E-14S-5S CONN 5S CABLE2.00012-200098 EACH 720-8034 CONN 9S D1.00012-200110 EACH MS3420-6 CONN .312 BOOT2.00012-200111 EACH MS3420-4 CONN SMALL BOOT1.00012-200141 EACH MS3116F16-26S CABLE CONN 26S2.00012-300029 EACH 510-2400 CONN 9 DIN CLAMP1.00012-300148 EACH CBL &CHRGR END RED EXPOSED PIN4.00013-000018 FOOT 8523 WIRE 20GA BLACK INSULATED4.00013-000023 FOOT 8523 WIRE 20GA RED INSULATED6.00013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED1.00013-000031 FOOT 8524 WIRE 22GA GRAY INSULATED1.00013-000032 FOOT 8524 WIRE 22GA ORANGE INSULATD1.00013-000034 FOOT 8524 WIRE 22GA VIOLET INSULATD1.00013-000035 FOOT 8524 WIRE 22GA WHITE INSULATED4.00013-000036 FOOT 8524 WIRE 22GA YELLOW INSULATD4.00013-100001 FOOT 942802 CBL 2 WIRE #28 SHIELDED4.00013-100022 FOOT 2254/1 CBL 1 WIRE #22 SHIELDED5.00013-100025 FOOT UWP1652-B CABLE 2 WIRE LEADER

10.00013-300002 FOOT 1/4 BLACK EXPANDO SHEATHING2.00015-000022 EACH ATC-7 1/2 AMP BLADE FUSE2.00015-000025 EACH HHG FUSE HOLDER INLINE BLADE2.00019-000033 EACH 1080303001 BLACK BANANA PLUG1.00019-000037 EACH 18290 BLK BANANA PLUG SPLICE1.25103-000010 FOOT 1/16 SHRINK TUBING0.17103-000011 FOOT 1/2 SHRINK TUBING0.50103-000012 FOOT 1/4 SHRINK TUBING1.25103-000013 FOOT 1/8 SHRINK TUBING0.50103-000014 FOOT 3/16 SHRINK TUBING0.50103-000015 FOOT 3/16 SHRINK TUBING RED0.25103-000087 EACH 1 1/2 SHRINK TUBING


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Page 3.2b

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Page 3.2c


101-100226Revision: 000

CABLE RADIO INTERCONNECT

Bill of Materials:


1.00012-200110 EACH MS3420-6 CONN .312 BOOT1.00012-200126 EACH MS3101A-14S-5P CONN 5P CABLE1.00012-300140 EACH MS3057-6A CABLE CLAMP1.00013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED1.00013-000029 FOOT 8524 WIRE 22GA BROWN INSULATED1.00013-000032 FOOT 8524 WIRE 22GA ORANGE INSULATD1.00013-000033 FOOT 8524 WIRE 22GA RED INSULATED1.00013-000036 FOOT 8524 WIRE 22GA YELLOW INSULATD1.00013-300002 FOOT 1/4 BLACK EXPANDO SHEATHING


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Page 3.2d


101-100958Revision: 000

RADIO INTERCONNECT ICOM F520S

Bill of Materials:


1.00006-600211 EACH RES 1/4W 1% 33.2K OHM1.00012-200094 EACH 720-8029 CONN 9P D1.00012-200111 EACH MS3420-4 CONN SMALL BOOT1.00012-300029 EACH 510-2400 CONN 9 DIN CLAMP2.00012-300036 EACH D20418-50 CONN D MNTING SCREW1.00101-100226 EACH CBL RADIO INTERCONNECT N/CONN

2/16/2004Print Date: Page: 1 8:42:58AM Drawn By: MRG Approved By:


101-100978Revision: 000

RTI Y-CABLE

Bill of Materials:


1.00012-200095 EACH DEM9PL CONN 9P D 90D PCB1.00012-200098 EACH 720-8034 CONN 9S D2.00012-200111 EACH MS3420-4 CONN SMALL BOOT2.00012-300029 EACH 510-2400 CONN 9 DIN CLAMP1.00012-300036 EACH D20418-50 CONN D MNTING SCREW

10.00013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED5.00013-000028 FOOT 8524 WIRE 22GA BLUE INSULATED5.00013-000030 FOOT 8524 WIRE 22GA GREEN INSULATED5.00013-000035 FOOT 8524 WIRE 22GA WHITE INSULATED

10.00013-300002 FOOT 1/4 BLACK EXPANDO SHEATHING0.12103-000013 FOOT 1/8 SHRINK TUBING



101-100163MRevision: 000

SHOT PRO II UNIT

Bill of Materials:


1.00017-000121 EACH TCSD-17-D-05.00-01-N SP11 JPFP1.00019-000300 EACH PELCO PART SERIAL# LABEL4.00019-000550 EACH SCREW 6-32 X 3/8 BH SS

10.00019-000653 EACH SCREW 8-32X5/8 SOCKET HEAD SS4.00019-000678 EACH 617-6635 FOOT PAD .5 X .21.00101-100152M EACH SHOT PRO II ENCLOSURE ASSEMBLY1.00101-100164M EACH SHOT PRO II FRONT PANEL & ASSY1.00101-100908M EACH SHOT PRO II CARD-11.00101-100933 EACH SHOT PRO II STANDARD GPS CARD1.00103-000032 EACH CORROSION INHIBITOR VCI 101


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Page 4.1


101-100152MRevision: 000

SHOT PRO II ENCLOSURE ASSEMBLY

Bill of Materials:


2.00019-000067 EACH 1238/1SS ARMORED BUTTON COVER4.00019-000122 EACH 3363 WASHER NYLON4.00019-000148 EACH WASHER #8 INTERNAL LK1.00019-000226 EACH KEP HEX NUT 4-402.00019-000348 EACH 01-1034-1-0312RED BINDING POST3.00019-000519 EACH SCREW 4-40 X 5/16 PAN PHIL SS1.00019-000528 EACH SCREW 4-40 X 7/16 PH PHL SS4.00019-000597 EACH SCREW 8-32 X 3/8 PAN PHIL SS1.00019-000642 EACH PE9251 SMA TO TNC FEMALE BLKHD1.00075-100169 EACH SHOT PRO II ENCLOSURE PAINTED1.00101-100144 EACH SHOT PRO II JF WIRING HARNESS1.00101-100157 EACH SHOT PRO II JPAC WIRING HARNES1.00101-100161 EACH SHOT PRO II FIRING LINE CARD-12.00101-100927 EACH SHOT PRO II STRAP ASSEMBLY


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Page 5.1a

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Page 5.1b


101-100144Revision: 000

SHOT PRO II JF WIRING HARNESS

Bill of Materials:


1.00012-100018 EACH MS3112E16-26P CHASIS CONN 26P1.00012-200142 EACH 22-01-3097 CONN 9S CRIMP CABLE1.00012-300110 EACH 10-040450-16S SHIELD GSKT #168.00012-300115 EACH 08-65-0816 CONN 22-30AWG CRIMP1.00012-300127 EACH 16-26.30 CONN 26P EMI FILTER1.00013-000019 FOOT 8523 WIRE 20GA BLUE INSULATED0.50013-000023 FOOT 8523 WIRE 20GA RED INSULATED0.50013-000028 FOOT 8524 WIRE 22GA BLUE INSULATED0.50013-000032 FOOT 8524 WIRE 22GA ORANGE INSULATD0.50013-000036 FOOT 8524 WIRE 22GA YELLOW INSULATD0.50017-000122 EACH TCSD-20-D-24.00-01-N-R CABLE2.00019-000414 EACH 1412-4 LUG #4 5/8 LONG3.00103-000005 EACH 2 DIAM. BLACK CABLE TIE0.42103-000010 FOOT 1/16 SHRINK TUBING

12/4/2003Print Date: Page: 111:59:24AM Drawn By: MRG Approved By:

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Page 5.1c

mgray

Page 5.1d


101-100157Revision: 000

SHOT PRO II JPAC WIRING HARNES

Bill of Materials:


2.00009-300001 EACH 4PB11T2 PB 4PST MOMENTARY BLK1.00012-200001 EACH 22-01-3107 CONN 10S CRIMP CBL9.00012-300115 EACH 08-65-0816 CONN 22-30AWG CRIMP2.00013-000008 FOOT 8522 WIRE 18GA BLACK INSULATED2.00013-000014 FOOT 8522 WIRE 18GA RED INSULATED1.00013-000028 FOOT 8524 WIRE 22GA BLUE INSULATED0.75013-000029 FOOT 8524 WIRE 22GA BROWN INSULATED1.00013-000030 FOOT 8524 WIRE 22GA GREEN INSULATED1.00013-000032 FOOT 8524 WIRE 22GA ORANGE INSULATD0.50013-000036 FOOT 8524 WIRE 22GA YELLOW INSULATD5.00103-000005 EACH 2 DIAM. BLACK CABLE TIE


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Page 5.1e


101-100161Revision: 000

SHOT PRO II FIRING LINE CARD-1

Bill of Materials:


2.00001-200041 EACH 1204-050 EMI FILTER 500WV OF1-22.00003-000015 EACH DIOD AC240L SURGE ARRESTOR DT1-21.00012-200020 EACH 09-50-8031 CONN 3S CABLE2.00012-300125 EACH 08-58-0189 PIN FOR JC8 SOCKET0.60013-000012 FOOT 9899 WIRE 18GA RED INSULATD HV0.25013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED1.00019-000416 EACH 1412-8 LUG #8 5/8 LONG1.00075-000029 EACH PCB SHOT PRO II FIRING LINE-1A0.08103-000013 FOOT 1/8 SHRINK TUBING0.04103-000019 FOOT 3/8 SHRINK TUBING


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Page 5.1h


101-100164MRevision: 000

SHOT PRO II FRONT PANEL & ASSY

Bill of Materials:


1.00017-000048 EACH SHOT PRO II INTERFACE CARD1.00017-000119 EACH SHOT PRO II FRONT PANEL1.00017-000143 EACH SHOT PRO II LED CRD & CBL ASSY4.00019-000512 EACH SCREW 4-40 X 3/8 PH PHL SS4.00019-000616 EACH 8763 SPACER 4-40X1/4X3/16 RND2.25019-000692 EACH SHOT PRO II FRONT PANEL SEAL1.00019-000693 EACH SHOT PRO II DISPLAY SHIELD1.00075-100167 EACH SHOT PRO II LID PAINTED1.00101-100959 EACH SHOT PRO II DISPLAY W/CBL ASSY


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Page 6.1

1

7

54

6

3

9

2

8

13

1110

12

19

1716

18

15

25

2322

24

21

31

2928

30

27

3736353433

4039

26

20

14

38

32

PPC

678910

345

21PPAC

+

789

123456

31323334

2526272829

192021

2322

1314151617

1011

24

30

12

18

34P2MHDR-TH

PPFP

+

321

PC3-1

PPFL

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Page 7.1a


101-100908MRevision: 000

SHOT PRO II CARD-1

Bill of Materials:


2.00001-000009 EACH AD822AR RAIL 2 RAIL OP AMP SMT U9, U132.00001-000011 EACH AD824AR RAIL 2 RAIL OP AMP SMT U12, U141.00001-000041 EACH PGA204AU OP AMP SOICW U81.00001-100009 EACH LTC1440IS8 SINGLE/DUAL SOIC U191.00001-200008 EACH DS1233DZ-15 5V RESET SOT223 U71.00001-200018 EACH ADM208ARS RS232 DRVRS/RCVRS U31.00001-200049 EACH LM334Z CURRENT REGULATOR U111.00001-200064 EACH LT1030CS RS232 QUAD LOW POWER U101.00001-200065 EACH LM2675M-5.0 VOLTAGE REG 5V VR12.00001-200067 EACH HCPL2201-300 LOGIC GATE SMT-G8 U17-181.00001-200068 EACH MAX4420ESA HI SPEED DRVR SOIC U201.00001-200069 EACH AD5301BRT VOLTAGE OUT 8BIT DAC U53.00001-300023 EACH FDC655AN N-CH LEVEL MOSFET U22, U26-272.00001-300050 EACH MC74HC32AD QUAD 2IN OR GATE U1, U151.00001-300071 EACH LTC1983ES6-5 CHRGE PUMP INVRTR U281.00001-300072 EACH MM74HC139M-M16A DUAL 2-4 LINE U21.00001-400012 EACH DS1245YP-70 SRAM 256K SMT U61.00001-600079 EACH PROGMD SHOT PRO II H8S1.00002-200003 EACH XSTR FDH44N50 FET HC TO-247 Q11.00003-000007 EACH DIOD S1B/113 RECTIFIER 1A CR10

12.00003-000014 EACH DIOD BAV99 DUAL SWITCHING CR1, CR4-8, CR12, CR16-CR204.00003-000016 EACH DIOD SK36A SHCOTTKY REC CR9, CR13-151.00003-100006 EACH DIOD DZ1N5222B 2.5V 500MW ZNR CR112.00003-100017 EACH BZX84C5V6 DIOD 350MW SOT-23 CR2-31.00004-000008 EACH VTA2-2A0 20.0 MHZ M11.00004-100004 EACH OPT AQV212 COUPLED RELAY U293.00004-100008 EACH TIL197A-SM OPT COUPLR ISOLATOR U21, U23-241.00004-200008 EACH 3J-1J1 GAS DISCHRGE TUB DT13.00005-000001 EACH MTP107M035PIC ELE 100MF 35V C39, C45, C62

10.00005-000005 EACH 293D106X0035D2T TAN 10 MF 20% C5, C8, C18-20, C22, C42, C49-50, C721.00005-000011 EACH 381LQ101M450J012 CAP 100uF C341.00005-300001 EACH C0805C103M5RACTR CER.01 PF20% C405.00005-300002 EACH CAP CER .0018 MF 5% 1206 C14, C23-25, C282.00005-300004 EACH CAP C0805100J1GAC CER 10PF 1% C10, C172.00005-300006 EACH C0805C220J1GAC CER 22 PF 5% C12, C264.00005-300007 EACH CAP CER 680 PF 5% 0805 C9, C13, C29, C483.00005-300012 EACH GP110 CAP CER .01 MF 1KV C37-38, C69

39.00005-300016 EACH CAP C0805C104KSRAC CER .1 MF C1-4,6-7,11,16,21,27,31-33,35-36 41,43-44,46-47,51-61,63-68,70-71

3.00005-300021 EACH C1206C104J5RAC CER 0.1MF 5% C30, C15A-B2.00006-500004 EACH RES 1/8W 1% 2K OHM 1206 R9, R327.00006-500005 EACH RES 1/8W 1% 402 OHM 1206 R19-20, R26-27, R45, R57, R681.00006-600041 EACH RES 1/4W 1% 100K OHM R521.00006-600102 EACH RES 1/4W 1% 178K OHM R421.00006-600115 EACH RES 1/4W 1% 1M OHM R501.00006-600144 EACH RES 1/4W 1% 20K OHM R702.00006-600205 EACH RES 1/4W 1% 301 OHM R51, R541.00006-600293 EACH RES 1/4W 1% 54.9K OHM R411.00006-700001 EACH RES 5W 1% .5 OHM 500V R551.00006-700002 EACH CRCW0805143FT .10W 1% 1.43K R481.00006-700003 EACH CRCW08051003FTX .10W 1% 100K R26.00006-700004 EACH RES 1/10W 1% 100 OHM R18, R25, R31, R74-75, R775.00006-700006 EACH CRCW08051002FT .10W 1% 10K OHM R5, R37, R39-40, R60


mgray

Page 7.1c


1.00006-700007 EACH CRCW080050100FT RES .10W 1% 10 R616.00006-700011 EACH CRCW08051001FT 1/10W 1% 1K OHM R14-15, R47, R58-59, R671.00006-700013 EACH CRCW08052151FT 1/10W 1% 2.15K R711.00006-700016 EACH CRCW08052741FT .10W 1% 2.74K R30

12.00006-700017 EACH CRCW08052002FT 1/10W 1% 20K R3, R6-7, R16-17, R21-22, R64, R66, R72-73, R76

2.00006-700018 EACH RES 1W 1% 20K OHM R53, R561.00006-700024 EACH CRCW08053920FT RES .10W 1% 392 R283.00006-700026 EACH CRCW08054991FT 1/10W 1% 4.99K R23, R46, R494.00006-700027 EACH CRCW08054022FT 1/10W 1% 40.2K R33-361.00006-700028 EACH RES 1/10W 1% 402K OHM 0805 R84.00006-700031 EACH RES 1/10W 1% 49.9K OHM 0805 R4, R10, R12-132.00006-700039 EACH CRCW08053012FT 1/10W 1% 30.1K R11, R381.00006-700040 EACH CRCW08051211FT RES.10W 1%1.21K R431.00006-700052 EACH CRCW08052001FT RES 1/10W 1% 2K R441.00006-800008 EACH 3262W-1-103 RES POT 10K HI TRN R242.00006-900012 EACH SOMC-1601-223G RES NET 22K OHM RP62-631.00007-000008 EACH LQH32CN101K21L L12.00007-000009 EACH LQH3C101K34 INDUCTOR 100MH SMT L2-31.00007-000011 EACH IDCS-7328-68 INDUCTOR 68MH L41.00008-000002 EACH SP66 XFMR 10K TO 10K CT/CT T21.00008-000003 EACH SP69 XFMR T31.00008-000005 EACH CMF2-2503SM XFMR HORZTL FILTR T13.00009-400015 EACH 1-1437586-2 SW DIP 4PST SMT S1-S32.00010-000010 EACH DF2E-DC5V RELAY 5V DIP MINATUR K2-31.00010-000014 EACH AQW224NA RELAY PHOTO COUPL SMT K11.00010-000016 EACH FTR-F1AA012T RELAY 5A 0.53W K41.00012-000018 EACH 22-11-2102 CONN 10P PCB PPAC1.00012-000057 EACH CONN 4P TERM STRIP PPDB2.00012-000072 EACH 104655-7 CONN 60P SMT HEADER JA, JB1.00012-000078 EACH EHT-120-01-S-D-SM CONN 40P SMT PPC1.00012-000080 EACH EHT-117-01-S-D CONN 34P 2MM PPFP1.00012-200077 EACH 26-48-2035 CONN 3P STRAIGHT PPFL1.00012-300105 EACH 111-93-306-41001 CONN 6P DIP XU291.00016-000005 EACH PS DS9034PC LITHIUM BATTERY1.00016-000036 EACH LF101S PS 5V IN/OUT 1W CONVRTR PS21.00016-000038 EACH LT1617ES5-1 PS 1-15V DC/DC CVT U41.00016-000039 EACH PWR SUPPLY 400 VOLTS S3-S400 PS13.00019-000226 EACH KEP HEX NUT 4-40 XQ1,2.00019-000525 EACH SCREW 4-40 X 5/8 PAN PHIL SS1.00019-000528 EACH SCREW 4-40 X 7/16 PH PHL SS XQ12.00019-000622 EACH 9147 SPACER 4-40 X 1/4 HEX1.00075-000298 EACH PCB SHOT PRO II CARD-1C


mgray

Page 7.1c

A8

A5

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6/D

A0

P16

/PO

14/T

I0C

A2

P17

/PO

15/T

IOC

B2/

TCLK

D

P13

/PO

11/T

IOC

D0/

TCLK

B

P10

/PO

8/TI

0CA

0/D

AC

K0

P11

/PO

9/TI

0CB

0/D

AC

K1

P14

/PO

12/T

IOC

A1

+5V

D

P10

/PO

8/TI

0CA

0/D

AC

K0

CO

RR

EC

TED

CA

PA

CIT

OR

FO

OTP

RIN

TS12

/99

JP60

-S

47 48 49 50 51 52 53 54 55 56 57 58 59 6038 39 40 41 42 43 44 45 4637363534333231302919 2827262524232221201817161514131211107 8 941 2 3 5 6JA

98P

51/R

XD

297

P50

/TX

D2

96P

F0/B

RE

Q1

PG

3/C

S1

31P

A6/

A22

/IRQ

632

PA

7/A

23/IR

Q7

95P

F1/B

AC

K

93P

F3/L

WR

92P

F4/H

WR

91P

F5/R

D90

PF6

/AS

88P

F7/P

HI

86E

XTA

L85

XTA

L83

STB

Y82

NM

I81

RE

S80

WD

TOV

F79

P20

/P00

/TIO

CA

378

P21

/P01

/TIO

CB

3

33P

67/C

S7 /

IRQ

3

2P

G4/

CS

0

34P

66/C

S6 /

IRQ

2

41D

142

D2

43D

345

D4

48D

7

55D

13

94P

F2/W

AIT

/BR

EQ

0

77P

22/P

02/T

IOC

3/TM

RI0

74P

25/P

05/T

IOC

B4/

TMC

I1

76P

23/P

03/T

IOC

D3/

TMC

I075

P24

/P04

/TIO

CA

4/TM

RI1

114

VS

S

100

VS

S

99V

SS

87V

SS

68V

SS

67V

SS

65V

SS

53V

SS

44V

SS

66P

60/C

S4

69P

61/T

EN

D0 /

CS

5

70P

62/D

RE

Q1

71P

63/T

EN

D1

3V

SS

4V

SS

10V

SS

19V

SS

28V

SS

35V

SS

36V

SS

56D

1457

D15

59P

30/T

XD

0

61P

32/R

XD

062

P33

//RX

D1

63P

34/S

CK

064

P35

/SC

K1

72P

27/P

07/T

IOC

B5/

TMO

1

73P

26/P

06/T

IOC

A5/

TMO

0

37P

65/IR

Q1

38P

64/IR

Q0

40D

0

46D

547

D6

49D

850

D9

51D

1052

D11

54D

12

60P

31/T

XD

1

108

P43

/AN

310

7P

42/A

N2

106

P41

/AN

110

5P

40/A

N0

104

VR

EF

103

AV

CC

102

AD

TRG

101

SC

K2

13P

C6/

A6

117

14P

C7/

A7

15P

B0/

A8

16P

B1/

A9

17P

B2/

A10

18P

B3/

A11

20P

B4/

A12

21P

B5/

A13

22P

B6/

A14

23P

B7/

A15

24P

A0/

A16

25P

A1/

A17

26P

A2/

A18

27P

A3/

A19

29P

A4/

A20

/IRQ

430

PA

5/A

21/IR

Q5

116

P16

/PO

14/T

IOC

A2

115

109

P44

/AN

4

110

P45

/AN

5

111

P46

/AN

6/D

A0

112

P47

/AN

7/D

A1

113

AV

SS

118

P14

/PO

12/T

IOC

A1

119

120

121

122

12P

C5/

A5

11P

C4/

A4

9P

C3/

A3

8P

C2/

A2

7P

C1/

A1

6P

C0/

A0

39V

CC

5V

CC

84V

CC

58V

CC

89V

CC

123

MD

0

124

MD

1

125

MD

2

126

PG

0/C

AS

/OE

127

PG

1/C

S3

128

PG

2/C

S2

HD

64F2

357

U1

4748495051525354555657585960 383940414243444546 37 36 35 34 33 32 31 30 29 1928 27 26 25 24 23 22 21 20 18 17 16 15 14 13 12 11 10 789 4 12356

PC

B -

DA

TE

2B -

06/1

8/01

2 - 0

5/25

/99

PR

OD

UC

TIO

N

2C -

05/1

3/03

2A -

08/2

4/99

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Page 7.2a


001-600079MRevision: 000

PROGMD SHOT PRO II H8S

Bill of Materials:


1.00001-500013 EACH HD64F2357F20 H8S/2357 IC14.00005-300016 EACH CAP C0805C104KSRAC CER .1 MF CD1-41.00006-700052 EACH CRCW08052001FT RES 1/10W 1% 2K2.00012-000002 EACH 104652-6 CONN 60S 50/50 SMT JA, JB1.00075-000283 EACH PCB H8S MICROPROCESSOR 2C


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Page 7.2c

06/16/03

02/28/03

7543 61 2

P1

87 94 521 3 6

PPG

29 30 31 32 33 34 35 36 37 38 39 4016131211 151481 2 3 764 9 10 17 18 19 20 21 22 23 24 25 26 27 285


101-100933MRevision: 000

SHOT PRO II STANDARD MOUNTING

Bill of Materials:


2.00001-200070 EACH LT1780ISW LOW POWER RS232 5V U1-210.00005-300016 EACH CAP C0805C104KSRAC CER .1 MF C6-15

2.00006-700017 EACH CRCW08052002FT 1/10W 1% 20K R5-62.00006-700052 EACH CRCW08052001FT RES 1/10W 1% 2K R7-81.00012-200143 EACH 22-12-2094 CONN 9P PCB 90 DEG PPG1.00016-000001 EACH PS BATT 3.6V 1/2AA LITHIUM BT11.00017-000123 EACH KSM1193-06-SMAP ANTENNA CBL 6"1.00017-000128 EACH GN-79N FURUNO RECEIVER1.00017-000136 EACH 51065-0700-8 GPS CABLE FURUNO4.00019-000226 EACH KEP HEX NUT 4-404.00019-000361 EACH 2102-440-SS SPACER 4-40 X 3/84.00019-000525 EACH SCREW 4-40 X 5/8 PAN PHIL SS1.00075-000285 EACH SHOT PRO II HV SHIELD CARD1.00075-000290 EACH SHOT PRO II GPS MNTING CARD-1A1.00103-000005 EACH 2 DIAM. BLACK CABLE TIE


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Page 8.1c


101-100940Revision: 000

SHOT PRO II ENCODER MNT BRKT

Bill of Materials:


3.00019-000166 EACH 150-PH-18 SHOCK MOUNT 18 POUND12.00019-000215 EACH HEX KEP NUT 10-3212.00019-000399 EACH SCREW 10-32 X 3/8 FH SS

2.00019-000450 EACH 23035 STRAP 3/4X24 W/BUCKLE1.00075-100292 EACH SHOT PRO II ENCODER MOUNTING


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Page 9.1


101-100922Revision: 000

SHOT PRO II BACKPACK ASSEMBLY

Bill of Materials:


1.00012-300148 EACH CBL &CHRGR END RED EXPOSED PIN1.00017-000140 EACH 624-085-0039 BACKPACK SHOLDER1.00017-000141 EACH 624-070-0036 BACKPACK BELT1.00017-000144 EACH SHOT PRO II BACKPACK COVER4.00019-000492 EACH SCREW 4-40 X 1/4 PAN PHIL SS1.00019-000687 EACH SHOT PRO II FOAM BACKPACK2.00075-100278 EACH SHOT PRO II ANTENNA ANGLE1.00075-100300 EACH SPII ANTENNA MOUNTING PLATE


mgray

Page 10.1

06/16/03

7543 61 2

P1

02/28/03

87 94 521 3 6

PPG

29 30 31 32 33 34 35 36 37 38 39 4016131211 151481 2 3 764 9 10 17 18 19 20 21 22 23 24 25 26 27 285


101-100923MRevision: 000

SHOT PRO II SUB-METER MOUNTING

Bill of Materials:


1.00001-200043 EACH DP68L8B-500HZ BUTRWRTH FLTR VR14.00001-200070 EACH LT1780ISW LOW POWER RS232 5V U1-41.00003-000007 EACH DIOD S1B/113 RECTIFIER 1A CR21.00003-000016 EACH DIOD SK36A SHCOTTKY REC CR12.00005-000001 EACH MTP107M035PIC ELE 100MF 35V C2, C51.00005-300001 EACH C0805C103M5RACTR CER.01 PF20% C31.00005-300007 EACH CAP CER 680 PF 5% 0805 C4

17.00005-300016 EACH CAP C0805C104KSRAC CER .1 MF C1, C6-211.00006-700007 EACH CRCW080050100FT RES .10W 1% 10 R21.00006-700011 EACH CRCW08051001FT 1/10W 1% 1K OHM R42.00006-700017 EACH CRCW08052002FT 1/10W 1% 20K R5-62.00006-700026 EACH CRCW08054991FT 1/10W 1% 4.99K R1, R32.00006-700052 EACH CRCW08052001FT RES 1/10W 1% 2K R7-81.00007-000011 EACH IDCS-7328-68 INDUCTOR 68MH L11.00012-000081 EACH HLE-120-02-S-DV-BE-LC CONN 40S JP11.00012-200143 EACH 22-12-2094 CONN 9P PCB 90 DEG PPG1.00017-000034 EACH NOVATEL OEM4-3111R GPS RECEIVR8.00019-000197 EACH 16FW004032 WSH 1/4OD X .115ID8.00019-000226 EACH KEP HEX NUT 4-404.00019-000490 EACH SCREW 4-40 X 1/2 PH PHL SS4.00019-000614 EACH 8760 SPACER 4-40X1/4X 1/8 RND1.00075-000290 EACH SHOT PRO II GPS MNTING CARD-1A


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Page 11.1c


101-100088MRevision: 000

UPHOLE SIMILATOR UNIT-2

Bill of Materials:


1.00001-300061 EACH AT90S2313 8BIT MICROCNTROLR2.00009-000010 EACH 8A2021 SW DPDT CENTER OFF2.00009-300005 EACH 913 SW PUSH BUTTON SPDT BLACK1.00011-000011 EACH SSL-LX5093GD GREEN LAMP3.00011-000013 EACH LED L-53SRC/E RED SUPER BRIGHT4.00011-200001 EACH CLR301CTP 5MM CLEAR LENSE MNT4.00011-200007 EACH 5MM LENSE RETAINER RING2.00012-100016 EACH 3778 CONN BNC ISOLATED CHASSIS1.00012-200019 EACH 3399-7000 CONN 26S CABLE1.00012-200022 EACH 22-01-3037 CONN 3S CRIMP CBL PS11.00012-200096 EACH FCC17-E09PM-210 CONN 9P D FLTR2.00012-300035 EACH D20418-2 CONN D MNTING2.00012-300115 EACH 08-65-0816 CONN 22-30AWG CRIMP XPS11.00013-100008 FOOT 3302/26 RIBBON 26 WIRE FLAT6.00013-100025 FOOT UWP1652-B CABLE 2 WIRE LEADER1.00016-000014 EACH PS BATT 9V ALKALINE1.00017-000057 EACH 2243 BATT TERMINAL WIRE 9V1.00019-000015 EACH 1290-79 BATTERY HOLDER 9V2.00019-000033 EACH 1080303001 BLACK BANANA PLUG2.00019-000036 EACH 1080302001 RED BANANA PLUG1.00019-000037 EACH 18290 BLK BANANA PLUG SPLICE4.00019-000204 EACH 12SWS1014 WASHER 7/16 NYLON1.00019-000300 EACH PELCO PART SERIAL# LABEL2.00019-000369 EACH MS16535-26 RIVET 1/164.00019-000460 EACH SCREW 2-56 X 3/8 PAN PHIL SS2.00019-000640 EACH 1210 STRAIN RELIEF 1/8X5/8DIA1.00019-000650 EACH UPHOLE SIMILARITY FP/O-2 LABEL1.00075-100069 EACH FAB 40-005 UPHOLE SIMULATOR EN1.00101-100928M EACH UPHOLE SIMULATOR CARD-30.17103-000011 FOOT 1/2 SHRINK TUBING


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Page 12.1a


101-100184Revision: 000

UPHOLE SIMILATOR FP ASSY-2

Bill of Materials:


2.00009-000010 EACH 8A2021 SW DPDT CENTER OFF2.00009-300005 EACH 913 SW PUSH BUTTON SPDT BLACK1.00011-000011 EACH SSL-LX5093GD GREEN LAMP3.00011-000013 EACH LED L-53SRC/E RED SUPER BRIGHT4.00011-200001 EACH CLR301CTP 5MM CLEAR LENSE MNT4.00011-200007 EACH 5MM LENSE RETAINER RING2.00012-100016 EACH 3778 CONN BNC ISOLATED CHASSIS1.00012-200019 EACH 3399-7000 CONN 26S CABLE1.00012-200096 EACH FCC17-E09PM-210 CONN 9P D FLTR2.00012-300035 EACH D20418-2 CONN D MNTING1.00013-100008 FOOT 3302/26 RIBBON 26 WIRE FLAT4.00019-000204 EACH 12SWS1014 WASHER 7/16 NYLON1.00019-000650 EACH UPHOLE SIMILARITY FP/O-2 LABEL


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Page 12.1b

mgray

Page 12.1c


101-100928MRevision: 000

UPHOLE SIMULATOR CARD-3

Bill of Materials:


1.00001-000009 EACH AD822AR RAIL 2 RAIL OP AMP SMT U31.00001-200001 EACH REG103UA-5 5 VOLT REG SO8 U11.00001-200008 EACH DS1233DZ-15 5V RESET SOT223 U21.00001-200069 EACH AD5301BRT VOLTAGE OUT 8BIT DAC U61.00001-200070 EACH LT1780ISW LOW POWER RS232 5V U41.00001-300061 EACH AT90S2313 8BIT MICROCNTROLR U53.00002-000002 EACH XSTR 2N3904 NPN GEN PURPOSE Q1-31.00003-000007 EACH DIOD S1B/113 RECTIFIER 1A CR43.00003-000014 EACH DIOD BAV99 DUAL SWITCHING CR5-72.00003-100005 EACH DIOD 1N4746A 18V 1W ZENER CR1-21.00004-000005 EACH XTAL 8 MHZ DS800 CR33.00005-000005 EACH 293D106X0035D2T TAN 10 MF 20% C16-182.00005-100009 EACH CAP ELE 220 MF C20-211.00005-300001 EACH C0805C103M5RACTR CER.01 PF20% C61.00005-300002 EACH CAP CER .0018 MF 5% 1206 C81.00005-300007 EACH CAP CER 680 PF 5% 0805 C9

11.00005-300016 EACH CAP C0805C104KSRAC CER .1 MF C1-5, C7, C10, C22-253.00005-600002 EACH CD6FC101J03 CAP SM 100 PF C13-152.00005-600021 EACH CAP SM 33 PF C11-122.00006-500005 EACH RES 1/8W 1% 402 OHM 1206 R22, R404.00006-500007 EACH RES 1/8W 1% 768 OHM 1206 R20, R35-371.00006-600001 EACH RES 1/4W 1% 1.02K OHM R61.00006-600032 EACH RES 1/4W 1% 1.82K OHM R51.00006-600129 EACH RES 1/4W 1% 2.49K OHM R122.00006-700001 EACH RES 5W 1% .5 OHM 500V R4, R113.00006-700004 EACH RES 1/10W 1% 100 OHM R10, R16, R283.00006-700006 EACH CRCW08051002FT .10W 1% 10K OHM R13, R25, R291.00006-700011 EACH CRCW08051001FT 1/10W 1% 1K OHM R7

14.00006-700017 EACH CRCW08052002FT 1/10W 1% 20K R1-2, R9, R14-15, R17-19, R21, R26-27, R30-31, R34

4.00006-700026 EACH CRCW08054991FT 1/10W 1% 4.99K R23-24, R32-334.00006-700052 EACH CRCW08052001FT RES 1/10W 1% 2K R3, R8, R38-391.00008-000002 EACH SP66 XFMR 10K TO 10K CT/CT T11.00012-000037 EACH 929715-01-13-15 CONN 26P PCB JA1.00012-000041 EACH 22-12-2034 CONN 3P 90D PCB JS11.00012-300089 EACH 11093320 CONN 20P DIP XU51.00075-000282 EACH PCB UPHOLE SIMULATOR CARD-3


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Page 12.1e


102-000134Revision: 000

SHOT PRO II HARDWARE SPARES

Bill of Materials:


2.00009-300001 EACH 4PB11T2 PB 4PST MOMENTARY BLK2.00016-000005 EACH PS DS9034PC LITHIUM BATTERY1.00018-000028 EACH SHOT PRO SPARES CASE4.00019-000067 EACH 1238/1SS ARMORED BUTTON COVER

20.00019-000148 EACH WASHER #8 INTERNAL LK5.00019-000226 EACH KEP HEX NUT 4-404.00019-000348 EACH 01-1034-1-0312RED BINDING POST

10.00019-000512 EACH SCREW 4-40 X 3/8 PH PHL SS20.00019-000519 EACH SCREW 4-40 X 5/16 PAN PHIL SS10.00019-000528 EACH SCREW 4-40 X 7/16 PH PHL SS10.00019-000597 EACH SCREW 8-32 X 3/8 PAN PHIL SS20.00019-000653 EACH SCREW 8-32X5/8 SOCKET HEAD SS10.00019-000678 EACH 617-6635 FOOT PAD .5 X .2

4.00019-000683 EACH 7717-107 NYLON MOUNTING PAD1.00101-000908 EACH SHOT PRO II CARD-11.00101-100959 EACH SHOT PRO II DISPLAY W/CBL ASSY

10.00103-000005 EACH 2 DIAM. BLACK CABLE TIE1.00103-000028 EACH BLUE LOCTITE #242 10ML1.00103-000071 EACH #1 FLAT TIP SCREWDRIVER1.00103-000072 EACH #2 FLAT TIP SCREWDRIVER1.00103-000081 EACH 1/4 INCH NUT DRIVER2.00103-000086 EACH 7122A45 ALLEN HEX KEY 9/64"1.00103-000088 EACH 26110 PHILLIPS SCREWDRIVER 1X6


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Page 13.1

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Page 14.1a


101-100977Revision: 000

SHOT PRO II ENCODE CBL WITH JE

Bill of Materials:


1.00012-200050 EACH MS3106E-14S-5S CONN 5S CABLE2.00012-200094 EACH 720-8029 CONN 9P D2.00012-200098 EACH 720-8034 CONN 9S D1.00012-200110 EACH MS3420-6 CONN .312 BOOT4.00012-200111 EACH MS3420-4 CONN SMALL BOOT1.00012-200141 EACH MS3116F16-26S CABLE CONN 26S1.00012-200148 EACH PT01A-14-18P-SR CONN 18 PIN4.00012-300029 EACH 510-2400 CONN 9 DIN CLAMP1.00012-300036 EACH D20418-50 CONN D MNTING SCREW

12.00013-000018 FOOT 8523 WIRE 20GA BLACK INSULATED12.00013-000023 FOOT 8523 WIRE 20GA RED INSULATED48.75013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED12.00013-000030 FOOT 8524 WIRE 22GA GREEN INSULATED36.00013-000031 FOOT 8524 WIRE 22GA GRAY INSULATED

0.75013-000032 FOOT 8524 WIRE 22GA ORANGE INSULATD12.75013-000033 FOOT 8524 WIRE 22GA RED INSULATED36.00013-000035 FOOT 8524 WIRE 22GA WHITE INSULATED12.00013-000036 FOOT 8524 WIRE 22GA YELLOW INSULATD48.00013-100004 FOOT 2254/2 CBL 2 WIRE SHIELDED12.00013-100022 FOOT 2254/1 CBL 1 WIRE #22 SHIELDED12.00013-300001 FOOT 1/2 BLACK EXPANDO SHEATHING60.75013-300002 FOOT 1/4 BLACK EXPANDO SHEATHING

2.00015-000022 EACH ATC-7 1/2 AMP BLADE FUSE2.00015-000025 EACH HHG FUSE HOLDER INLINE BLADE0.50017-000106 EACH 3110 BNC/BNC COAX 10FT CABLE1.25103-000010 FOOT 1/16 SHRINK TUBING0.50103-000012 FOOT 1/4 SHRINK TUBING1.25103-000013 FOOT 1/8 SHRINK TUBING0.50103-000014 FOOT 3/16 SHRINK TUBING0.50103-000015 FOOT 3/16 SHRINK TUBING RED0.25103-000017 FOOT 3/4 SHRINK TUBING


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Page 14.1b

mgray

Page 14.2a


101-100978Revision: 000

RTI Y-CABLE

Bill of Materials:


1.00012-200095 EACH DEM9PL CONN 9P D 90D PCB1.00012-200098 EACH 720-8034 CONN 9S D2.00012-200111 EACH MS3420-4 CONN SMALL BOOT2.00012-300029 EACH 510-2400 CONN 9 DIN CLAMP1.00012-300036 EACH D20418-50 CONN D MNTING SCREW

10.00013-000027 FOOT 8524 WIRE 22GA BLACK INSULATED5.00013-000028 FOOT 8524 WIRE 22GA BLUE INSULATED5.00013-000030 FOOT 8524 WIRE 22GA GREEN INSULATED5.00013-000035 FOOT 8524 WIRE 22GA WHITE INSULATED

10.00013-300002 FOOT 1/4 BLACK EXPANDO SHEATHING0.12103-000013 FOOT 1/8 SHRINK TUBING


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Page 14.2b

ShotPro II.022-000058B

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