Reference Receiver Based Digital Self-Interference Cancellation in MIMO Full-Duplex Transceivers Dani Korpi, Lauri Anttila, and Mikko Valkama Tampere University of Technology, Department of Electronics and Communications Engineering, Finland 10th International Workshop on Broadband Wireless Access
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Reference Receiver Based Digital
Self-Interference Cancellation in
MIMO Full-Duplex Transceivers
Dani Korpi, Lauri Anttila, and Mikko Valkama
Tampere University of Technology, Department of Electronics and
Communications Engineering, Finland
10th International Workshop on Broadband Wireless Access
Outline
• Introduction
• RF impairments in a full-duplex transceiver
• Reference receiver based structure
• Initial analysis with system calculations
• Reference receiver aided digital cancellation
procedure
• Waveform simulations
• Conclusion
2
Introduction
• Simultaneous trans-
mission and reception
at the same center fre-
quency is an appealing
scheme
– Increased data rate,
MAC level benefits,
etc.
3
f
t
f
t
Do
wn
link
Up
link
Uplink
Downlink
FDD TDD
f
t
Uplink & Downlink
Single channel
full-duplex
Introduction (cont.)
4
• However, it has
also its down-
sides
– Increased com-
plexity due to
self-interference
cancellation, RF
impairments,
etc.
Receiver chain
Transmitter chain
Tx
RxS
elf-in
terf
ere
nce
RF cancellation Digital cancellation
DAC
ADC
SI regenerationAttenuation
& delay
PA
RF impairments
• The self-interference (SI) signal is distorted in
numerous ways within the transceiver chain,
especially in the transmitter
– This affects the accuracy with which the SI
signal can be regenerated for cancellation in
the digital domain
– Advanced modeling is required to achieve a
sufficient amount of SI cancellation
5
Reference receiver based
structure
6
• A simple way of
avoiding the complex
modeling is to take
the reference signal
always from the PA
output
• Then, the digital
cancellation signal
would include all the
TX impairments
Receiver chain
Transmitter chain
Tx
RxS
elf-in
terf
ere
nce
RF cancellation Digital cancellation
DAC
ADC
SI regenerationAttenuation
& delay
PA
Reference
receiver
Reference receiver based
structure (cont.)
• The downside of this approach is the need for
additional receivers
– In essence, a trade-off between the
computational cost of digital cancellation and
RF hardware
• It is not obvious what is the optimal scheme
of utilizing the additional receivers
7
Detailed analysis
8
Receiver chainsAmplitude
& phase
matching
RF can-
cellation
Reference receiver chains
Transmitter chains
TX2
BPF LNA IQ Mixer LPF VGA
2x2
mu
ltip
ath
co
up
ling
ch
an
ne
l
ADC
LPFIQ MixerVGAPA DAC
Digital
cancellation
To detector
TX1
LPFIQ MixerVGAPADAC
Transmit bit
stream 1
Transmit bit
stream 2
BPF LNA IQ Mixer LPF VGA ADC
Amplitude
& phase
matching
Digital
cancellationRF can-
cellation
To detector
Attenuator
IQ Mixer VGA ADC
Attenuator
IQ Mixer ADCVGA
Attenuator
-30 dB
Attenuator
-30 dB
SI
regeneration
RX1
RX2
LPF
LPF
SOI
Initial performance comparison
with system calculations
3.12.2014 9
With the reference receiver based structure, even linear processing can
provide sufficient SI suppression with transmit powers up to 20-25 dBm.
-5 0 5 10 15 20 25-90
-80
-70
-60
-50
-40
-30
-20
-10
0
Transmit power (dBm)
Pow
er
of diff
ere
nt sig
nal c
om
ponents
(dB
m)
Linear Digital Cancellationwith Reference Receivers