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Achieving Single Channel, Full Duplex Wireless Communication

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Presentation on theme: "Achieving Single Channel, Full Duplex Wireless Communication"— Presentation transcript:

1 Achieving Single Channel, Full Duplex Wireless Communication
Jung Il Choi, Mayank Jain, Kannan Srinivasan, Philip Levis, Sachin Katti Stanford University Mobicom 10’

2 Wireless Channel – Half Duplex?
“It is generally not possible for radios to receive and transmit on the same frequency band because of the interference that results.” - Andrea Goldsmith, “Wireless Communications,” Cambridge Press, 2005. Reason: The signal from a local transmitting antenna is hundreds of thousands of times stronger than transmissions from other nodes.

3 Challenge for Full Duplex
Decoding method Subtract transmit signal from receive antenna signal Problem: Very strong self-interference ~70dB

4 We need 70 dB of self signal cancellation to enable full duplex communication

5 Existing cancellation techniques

6 Digital cancellation Rx Input Analog to Digital Converter (ADC)
Digital Signal Processing Analog to Digital Converter (ADC) Analog Rx Frontend Rx signal Rx signal Digital Signal Processing Digital to Analog Converter (DAC) Analog Tx front end Tx Output Tx signal Tx signal

7 Digital cancellation Digital Signal Processing Rx signal – Tx signal (subtract) Rx Input Analog to Digital Converter (ADC) Analog Rx Frontend Rx signal Rx signal Digital Signal Processing Digital to Analog Converter (DAC) Analog Tx front end Tx Output Tx signal Tx signal Achieves 15dB of cancellation. We need 70dB, but we take what we get

8 Why is Digital cancellation not perfect
Rx Signal Discrete values for digitizing disc values for digitizng .. any values would be mapped to closest of these samples and saved in memory .. During digital conversion, rx signal is mapped to discrete values

9 Why is Digital cancellation not perfect
Rx Signal Self Signal

10 Self Signal Rx Signal Tx Signal is much stronger than Rx signal, thus in presence of strong self interference, the resolution for Rx signal decreases on ADC digitized samples.

11 Analog cancellation Rx Input Digital Signal Processing Rx signal – Tx signal (subtract) Analog to Digital Converter Analog Cancellation circuits Analog Rx Frontend Rx signal Rx signal Analog Tx front end Tx Output Digital Signal Processing Digital to Analog Converter Tx signal Tx signal Achieves 25dB of cancellation. Together with 15dB of digital cancellation, we have 40dB of total cancellation Still need 30dB more cancellation to achieve 70dB of cancellation

12 Antenna Cancellation Two Transmit antennas, one Receive antenna ~30dB
Where to place the receive antenna? Distance from the two transmit antennas differs by an odd multiple of half the wavelength of the center frequency of transmission -- Signal add destructively

13 Antenna Cancellation - Performance

14 Antenna Cancellation - Performance

15 Antenna Cancellation - Performance

16 Antenna Cancellation - Performance

17 Antenna Cancellation - Bandwidth
Bandwidth constraint λ/2 offset is precise for one frequency BUT not for the whole bandwidth WiFi (2.4G, 20MHz) => ~0.26mm precision error

18 Antenna Cancellation - Bandwidth
Higher Bandwidth => Less Cancellation Higher Carrier Frequency => More Cancellation⇧

19 System Diagram Three steps Achieves ~70dB cancellation
Antenna Cancellation ~30dB Hardware Cancellation ~25dB Digital Cancellation ~15dB Achieves ~70dB cancellation

20 Evaluation – Aggregate Throughput
Median throughput 92% of ideal full-duplex

21 Evaluation – Link Reliability
Little loss in link reliability: 88% of half-duplex on average

22 Full Duplex - Applications
True benefit lies beyond the physical layer Breaks a basic assumption in wireless Can solve some fundamental problems with wireless networks Hidden terminals Reducing Congestion with MAC Scheduling Wormhole Routing in Multihop Networks Cognitive Radios

23 Mitigating Hidden Terminals
Full Duplex solves hidden terminals N2 hears the transmission from the access point and delays its transmission, thereby avoiding a collision.

24 Reducing Congestion with MAC Scheduling
Aggregate Network throughput: 1/n -> 1*link_cap (2n+1 nodes, star topology)

25 Wormhole Routing in Multihop Networks
Problem: Long delivery and round-trip times in multihop networks Solution: Forward a packet while receiving it

26 Limitations High Transmit Power Bandwidth Constraint
Time-varying wireless channel Auto-tuning of the hardware cancellation circuit Mayank Jain, Jung Il Choi, Taemin Kim, Dinesh Bharadia, Kannan Srinivasan, Siddharth Seth, Philip Levis, Sachin Katti and Prasun Sinha. “Practical, Real-time, Full Duplex Wireless.” In Proceedings of the 17th Annual International Conference on Mobile Computing and Networking (Mobicom 2011).

27 Questions

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