1. 7-July-2007
Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs)
Submission Title: [DecaWave Proposal for TG3c Alternative PHY]
Date Submitted: [2007-July-9th]
Source: [Michael Mc Laughlin, Brian Gaffney] Company [DecaWave]
Address [25 Meadowfield, Sandyford, Dublin 18, Ireland]
Voice:[ ], FAX: [none],
Re: [Response to Call for Proposals]
Abstract: [Alternative PHY Proposal for TG3c]
Purpose: [To assist TG3c in selecting a mm Wave PHY]
Notice: This document has been prepared to assist the IEEE P It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein.
Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P
Mc Laughlin, Gaffney, DecaWave

2. Outline: Modulation Scheme
7-July-2007
Outline: Modulation Scheme
Low complexity, high performance base mode
Base mode, 1.4 Gbps, enables non coherent receivers
simple, inexpensive devices can receive the same signal as more robust, coherent receivers
Two higher bit-rate modes, 2.8 Gbps and 4.2 Gbps are derived from this base mode
Mc Laughlin, Gaffney, DecaWave

3. Outline: AWGN Performance
7-July-2007
Outline: AWGN Performance
Parameter
Low
Base
High Rate
Very High Rate
Non Coherent
Bit Rate
67Mb/s
1.4Gb/s
2.8Gb/s
4.2Gb/s
Operating range (LOS)
51.6m
88m
50.2m
30.4m
13.3m
Operating range (NLOS) -
25m
15.9m
10.6m
Mc Laughlin, Gaffney, DecaWave

4. Outline: Channel Model Performance
7-July-2007
Outline: Channel Model Performance
Parameter
Base
High Rate
Very High Rate
Bit Rate
1.4Gb/s
2.8Gb/s
4.2Gb/s
Operating range (CM1.3 LOS)
88m
50m
29m
Operating range (CM3.1 LOS)
78m
43m
24m
Operating range (CM2.3 NLOS)
20m
9.5m -
Equalisation: Decision Feedback <20 Taps
Mc Laughlin, Gaffney, DecaWave

5. System Design 8-QAM constellation for all modes.
7-July-2007
System Design
8-QAM constellation for all modes.
Convolutional code concatenated with a GF(26) Reed Solomon code for additional error correcting capabilities
Different data rate modes are:
1.4 Gbps using an unpunctured convolutional code, or
2.8 Gbps using a punctured convolutional code, or
4.2 Gbps using no convolutional code
The base mode (1.4 Gbps) can be received by non-coherent receivers
Mc Laughlin, Gaffney, DecaWave

6. 8-QAM 8-QAM Allows for Non-Coherent reception Only two levels
7-July-2007
8-QAM
8-QAM
Used in the V.29 modem standard due to resilience to phase noise.
Higher bandwidth efficiency than QPSK.
More resilient to phase noise problems than higher order constellations (16-QAM or 8-PSK).
Allows for Non-Coherent reception
Only two levels
R1=√2, R0=1+√3 Q
001
100
101
000
010 I R1
111
110 R0
011
Mc Laughlin, Gaffney, DecaWave

7. 8-QAM Decision Boundaries
7-July-2007
8-QAM Decision Boundaries
001
100
101
000
010
111
110
011
Mc Laughlin, Gaffney, DecaWave

8. 7-July-2007
Inner Coding
Systematic Reed Solomon code is over the Galois field GF(26) and is given as RS(63,55)
Input of 55 symbols creates 8 parity symbols for a rate 0.87 code
Systematic code allows low complexity receivers to ignore the parity symbols
Currently used in IEEE a standard
Mc Laughlin, Gaffney, DecaWave

9. Interleaver An interleaver is placed between the Inner and Outer Code.
7-July-2007
Interleaver
An interleaver is placed between the Inner and Outer Code.
Errors from the Viterbi decoder occur in bursts
Interleaver separates these errors such that they occur in different RS code blocks.
This improves the performance significantly
Mc Laughlin, Gaffney, DecaWave

10. Outer Code: Convolutional Code
7-July-2007
Outer Code: Convolutional Code
Outer code is rate 1/3, K=4, systematic convolutional code
Low constraint length => complexity very low
With K=4, there are only 8 possible states.
Two parallel encoders/decoders used to reduce decoding clock rate even further
Mc Laughlin, Gaffney, DecaWave

11. Convolutional Code: Rate 1/3, K=4
7-July-2007
Convolutional Code: Rate 1/3, K=4 g1 g3 + g2 +
Generator Polynomial: g1=108, g2 = 118, g3 =168
Mc Laughlin, Gaffney, DecaWave

12. 7-July-2007
Convolutional Code
Systematic code gives the option of ignoring the parity bits
Important for Non-Coherent receiver. To be covered later.
However, systematic codes are known to perform worse than non-systematic.
The combination of this systematic code with this constellation mapping approaches the performance optimal non-systematic code with a Gray coded constellation
Mc Laughlin, Gaffney, DecaWave

13. Base Mode – 1.4Gbps Base mode Inner and Outer coding 8 QAM modulation
7-July-2007
Base Mode – 1.4Gbps
Base mode
One bit per symbol.
Data rate = 0.87*Bandwidth = 1.4 Gbps
Inner and Outer coding
Interleaver in between
8 QAM modulation
Mc Laughlin, Gaffney, DecaWave

14. Base Mode Transmitter Block Diagram
7-July-2007
Base Mode Transmitter Block Diagram
CCode
Const
Map RS
encode
Interleaver
Serial to
Parallel
Parallel to
Serial
CCode
Const
Map
Mc Laughlin, Gaffney, DecaWave

15. Base Mode Receiver Block Diagram
7-July-2007
Base Mode Receiver Block Diagram
Viterbi
Const
Demap
Parallel to
Serial
DeInterleaver RS
decode
Serial to
Parallel
Viterbi
Const
Demap
Mc Laughlin, Gaffney, DecaWave

16. PA and Phase Noise Simulation Parameters
7-July-2007
PA and Phase Noise Simulation Parameters
AM/AM distortion model
P = 1.6
Vsat = 2.09
G = 79.43
AM/PM distortion model
q = 3.5
A =
B =
OBO = 5dB
PN model
PSD(0) =
fp = 1Mhz, fz = 100Mhz.
Mc Laughlin, Gaffney, DecaWave

17. Proposed Band Plan U.S. Japan 57 59 64 66 f(Ghz) 3dB BW 1.6 Ghz
7-July-2007
Proposed Band Plan
U.S.
Japan
3dB BW 1.6 Ghz
400
MHz
400
MHz 1 2 3 4 57 59 64 66
f(Ghz)
~2.2Ghz
Separation
Mc Laughlin, Gaffney, DecaWave

18. Base Mode, 1.4Gbps AWGN Performance
7-July-2007
Base Mode, 1.4Gbps AWGN Performance
Includes
PN, PA
Mc Laughlin, Gaffney, DecaWave

19. High Data Rate Mode – 2.8Gbps
7-July-2007
High Data Rate Mode – 2.8Gbps
High Data Rate mode
Two bits per symbol
Punctured Base mode
Interleave RS output
Data rate = 2*0.87*Bandwidth = 2.8 Gbps
Same Tx as Base mode, but with symbol puncturing.
Mc Laughlin, Gaffney, DecaWave

20. High Data Rate Mode Puncturing
7-July-2007
High Data Rate Mode Puncturing s3 s4 s5 s6
Every second symbol is punctured in each of the parallel encoders/decoders.
Receiver the same as base mode.
Mc Laughlin, Gaffney, DecaWave

21. High Data Rate Mode 2.8Gbps AWGN Performance
7-July-2007
High Data Rate Mode 2.8Gbps AWGN Performance
Includes
PN, PA
Mc Laughlin, Gaffney, DecaWave

22. Very High Data Rate Mode – 4.2Gbps
7-July-2007
Very High Data Rate Mode – 4.2Gbps
Very High Data Rate mode
No convolutional code
Reed Solomon RS(63,55) encoder
Interleave RS output
Data rate = 3*0.87*Bandwidth= 4.2 Gbps
Mc Laughlin, Gaffney, DecaWave

23. Very High Data Rate Mode Transmitter
7-July-2007
Very High Data Rate Mode Transmitter RS
Mapping
Mc Laughlin, Gaffney, DecaWave

24. Very High Data Rate Mode 4.2Gbps AWGN Performance
7-July-2007
Very High Data Rate Mode 4.2Gbps AWGN Performance
Includes
PN, PA
Mc Laughlin, Gaffney, DecaWave

25. Non Coherent Demodulator – 1.4Gbps
7-July-2007
Non Coherent Demodulator – 1.4Gbps
The Non Coherent receiver is ideal for File Transfer or Kiosk modes
The systematic bit decides which “ring” the transmitted symbol is on. Therefore, by using a simple energy detector receiver we can decode the systematic bit from any base mode signal.
The Outer Reed Solomon code then gives some optional error correcting capabilities
Mc Laughlin, Gaffney, DecaWave

26. Compatible with ASK and OOK receivers.
7-July-2007
Non Coherent Mode
Compatible with ASK and OOK receivers.
Enables a very low cost, very low power, implementation
Ideal for integration into media players, phones, cameras etc.
Mc Laughlin, Gaffney, DecaWave

27. Non Coherent Mode 1.4Gbps AWGN Performance
7-July-2007
Non Coherent Mode 1.4Gbps AWGN Performance
Includes
PN, PA
Mc Laughlin, Gaffney, DecaWave

28. Summary AWGN Performance
7-July-2007
Summary AWGN Performance
Includes
PN, PA
Mc Laughlin, Gaffney, DecaWave

29. Low Data Rate Mode – 67Mbps
7-July-2007
Low Data Rate Mode – 67Mbps
Low data rate back channel mode.
Length 21 Ipatov ternary sequence.
+00−++−0+0+−+++++−−0−
Golay Merit Factor of 5.3
Reed Solomon RS(63,55) encoder
Gives the option of either 67Mbs or 133Mbs (high data mode) which is more resistant to errors
Mc Laughlin, Gaffney, DecaWave

30. Low Data Rate Mode Transmitter
7-July-2007
Low Data Rate Mode Transmitter RS
Spreading
Mc Laughlin, Gaffney, DecaWave

31. 7-July-2007
Hidden Node Problems
Major problem with directive antenna systems is finding Nodes.
To combat this problem, we propose using a single element mode.
For omni-directional antenna elements, we can now “see” in every direction.
For directive antenna elements, we can only “see” in the direction we can adapt in.
Mc Laughlin, Gaffney, DecaWave

32. 7-July-2007
Hidden Node Problems
However, the path loss is so high at 60Ghz, a very weak signal is received when we are not using the antenna array gain
The Solution:
Compensate for the lack of antenna array gain at Tx and Rx by spreading the signal to obtain an equal or higher processing gain
Mc Laughlin, Gaffney, DecaWave

33. Ternary Spreading Sequence
7-July-2007
Ternary Spreading Sequence
Ipatov Sequence
Perfect Periodic Autocorrelation properties.
Allows for accurate channel estimation for Channel Matched Filtering (CMF) and Antenna Array adaptation.
Used in a
For example, a length 183 sequence is equivalent to an antenna array gain of approximately 22.2 dBi
Many such sequences allows separate piconets to co-exist
Example length 183 Ipatov Sequence:
+−−−+0+−−−−−++−− −−++0+−+−+−+−−00−−+−+−++−−++−−+−0−−−++−−0−++−0−−+++−+++−−+−+−−+−+++++0−−++−−++−+−−− −0−−−−−+−++−−0++++−+−−−−+++−+−+−−++−++−+0−++++−+−++++−++− −+−−+
Mc Laughlin, Gaffney, DecaWave

34. Ternary Spreading Sequence
7-July-2007
Ternary Spreading Sequence
Periodic Auto Correlation of Length 183 Ipatov Sequence
Mc Laughlin, Gaffney, DecaWave

35. Ternary Spreading Sequence
7-July-2007
Ternary Spreading Sequence
With the perfect autocorrelation we can obtain an excellent estimate of the channel for the Channel Matched Filter (CMF)
Send 16 times before each packet
Mc Laughlin, Gaffney, DecaWave

36. Link Budget (LOS) PER 8% Parameter Low Base High Rate Very High Rate
7-July-2007
Link Budget (LOS) PER 8%
Parameter
Low
Base
High Rate
Very High Rate
Non Coherent
PHY-SAP Payload Bit Rate (Rb)
67Mb/s
1.4Gb/s
2.8Gb/s
4.2Gb/s
Average Transmit Power
10dBm
Transmit Antenna Gain
15dBi
Center frequency (fc)
60GHz
Path loss at 1 meter
68dB
Receive Antenna Gain
Average noise power per bit
-69.3dBm
-82.5dBm
-79.5dBm
-77.7dBm
Noise Figure
8dB
-74.5dBm
-71.5dBm
-69.7dBm
Minimum Eb/N0 for AWGN channel
2.5dB
4.6dB
6.5dB
9.2dB
20.2dB
Shadowing link margin
1dB
Implementation Loss
2dB
Tolerable path loss
34.25dB
39dB
34dB
29.6dB
22.5dB
Maximum operating range (d = 10 PL/10n,n=2)
51.6m
88m
50.2m
30.4m
13.3m
Mc Laughlin, Gaffney, DecaWave

37. Link Budget (NLOS) PER 8%
7-July-2007
Link Budget (NLOS) PER 8%
Parameter
Base
High Rate
Very High Rate
PHY-SAP Payload Bit Rate (Rb)
1.4Gb/s
2.8Gb/s
4.2Gb/s
Average Transmit Power
10dBm
Transmit Antenna Gain
15dBi
Center frequency (fc)
60GHz
Path loss at 1 meter
68dB
Receive Antenna Gain
Average noise power per bit
-82.5dBm
-79.5dBm
-77.7dBm
Noise Figure
8dB
-74.5dBm
-71.5dBm
-69.7dBm
Minimum Eb/N0 for AWGN channel
4.6dB
6.5dB
9.2dB
Shadowing link margin
5dB
Implementation Loss
2dB
Tolerable path loss
35dB
30dB
25.6dB
Maximum operating range (d = 10 PL/10n,n=2.5)
25m
15.9m
10.6m
Mc Laughlin, Gaffney, DecaWave

38. 7-July-2007
1.4Gbps CM1.3
Mc Laughlin, Gaffney, DecaWave

39. 7-July-2007
1.4Gbps CM2.3
Mc Laughlin, Gaffney, DecaWave

40. 7-July-2007
1.4Gbps CM3.1
Mc Laughlin, Gaffney, DecaWave

41. 7-July-2007
1.4Gbps distance summary
Mc Laughlin, Gaffney, DecaWave

42. 7-July-2007
2.8Gbps CM1.3
Mc Laughlin, Gaffney, DecaWave

43. 7-July-2007
2.8Gbps CM2.3
Mc Laughlin, Gaffney, DecaWave

44. 7-July-2007
2.8Gbps CM3.1
Mc Laughlin, Gaffney, DecaWave

45. 7-July-2007
2.8Gbps distance summary
Mc Laughlin, Gaffney, DecaWave

46. 7-July-2007
4.2Gbps CM1.3
Mc Laughlin, Gaffney, DecaWave

47. 7-July-2007
4.2Gbps CM3.1
Mc Laughlin, Gaffney, DecaWave

48. 7-July-2007
4.2Gbps distance summary
Mc Laughlin, Gaffney, DecaWave

49. Some slides symbolising the DecaWave proposal’s advantages
7-July-2007
Some slides symbolising the DecaWave proposal’s advantages
Mc Laughlin, Gaffney, DecaWave

50. Power Consumption High Complexity Solution
7-July-2007
Power Consumption High Complexity Solution
High Power Consumption
Mc Laughlin, Gaffney, DecaWave

51. Power Consumption DecaWave
7-July-2007
Power Consumption DecaWave
Moderate Power Consumption
Mc Laughlin, Gaffney, DecaWave

52. Power Consumption DecaWave Kiosk Mode
7-July-2007
Power Consumption DecaWave Kiosk Mode
Very Low Power Consumption
Mc Laughlin, Gaffney, DecaWave

53. Silicon Area High Complexity Solution
7-July-2007
Silicon Area High Complexity Solution
Lot of Silicon Required
Mc Laughlin, Gaffney, DecaWave

54. Silicon Area : DecaWave
7-July-2007
Silicon Area : DecaWave
Much Less Silicon Required
Mc Laughlin, Gaffney, DecaWave

55. Silicon Area : DecaWave in Kiosk Mode
7-July-2007
Silicon Area : DecaWave in Kiosk Mode
Hardly any Silicon Required
Mc Laughlin, Gaffney, DecaWave

56. Range : High Complexity Solution
7-July-2007
Range : High Complexity Solution
Quite Long Range Achievable
Mc Laughlin, Gaffney, DecaWave

57. Range : DecaWave Solution
7-July-2007
Range : DecaWave Solution
Just as Long
Mc Laughlin, Gaffney, DecaWave

58. Range : DecaWave in Kiosk Mode
7-July-2007
Range : DecaWave in Kiosk Mode
Long Enough
Mc Laughlin, Gaffney, DecaWave

59. Summary of DecaWave proposal
7-July-2007
Summary of DecaWave proposal
8-QAM modulation scheme
4 Data rates
Base mode of 1.4Gps obtained with outer RS (rate 0.87) and inner convolutional (rate 1/3) coding
High data rate mode of 2.8Gps obtained by puncturing base mode signal
Very high data rate mode of 4.2Gps obtained by using only RS code
Lower rate for back channel using Direct Sequence code
Systematic code developed specifically for the 8-QAM constellation which enables a Non-coherent receiver architecture
Mc Laughlin, Gaffney, DecaWave

60. Advantages Low Power, Low Complexity solution
7-July-2007
Advantages
Low Power, Low Complexity solution
Constellation resilient to RF impairments
Simple Non-coherent mode
Ideal for low cost receiver e.g. for media player
Single carrier
potential common signalling mode operation
More resistant to multipath
Ternary sequences and omni-directional antenna mode allows easy node discovery and channel estimation
Mc Laughlin, Gaffney, DecaWave