1. Tri-State HARQ Feedback for Aggressive HARQ Transmission
IEEE Presentation Submission Template (Rev. 9)
Document Number:
IEEE C802.16m-09/1465r1
Date Submitted:
Source:
Zheng Yan-Xiu, Yu-Chuan Fang, Chang-Lan Tsai, Chung-Lien Ho
ITRI
Venue:
IEEE m-09/0028r1, Call for contributions on 16m AWD content
“Comments on AWD HARQ Feedback A-MAP IE”
Base Contribution:
IEEE C802.16m-09/0894r4
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To be discussed and approval by IEEE m TG
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2. Motivation
Question 1: 1~5USD cost reduction can be achieved for each AMS device?
Question 2: 10 times throughput can be provided for an AMS given a HARQ soft buffer constraint?
Question 3: Reliable wireless link can be achieved when 10 times throughput is operated?
This three questions can be answered by YES.
This contribution provides the solution.

3. Aggressive HARQ Transmission
Tri-state HARQ mechanism
If decoded data is correct, MS feedbacks ACK
If decoded data is incorrect and the redundancy version can be completely stored in the HARQ buffer, MS feedbacks NACK
If decoded data is incorrect and redundancy version can not be completely stored in the HARQ buffer, MS feedbacks DROP
BS will retransmit the dropped packet when DROP is received, otherwise, BS will follow existing HARQ mechanism

4. Tri-State HARQ feedback
Aggressive HARQ transmission operates the HARQ mechanism beyond HARQ soft buffer capacity.
1~5 USD might be saved by reducing at least 100K~300K soft bits (5~30% ASIC size) on AMS side
Unreliable wireless transmission occurs due to lost of packet if 10 times transmission rate operates
We can not enjoy 10 times transmission rate and 1~5 USD cost reduction due to unreliable wireless transmission
Solution: Tri-State HARQ feedback maintains reliable wireless link
The feedback facilitates HARQ buffer management by three states ACK/NACK/DROP

5. Tri-State HARQ and HARQ Error Handling MAC Complexity Verification
HARQ Error Handling, AWD Draft 10r2, Page 47, Line 31-34
“In the absence (NULL detection) of an ACK or a NACK in the HARQ feedback channel assigned in the DL/UL Individual Persistent A-MAP IE, the ABS shall assume that the AMS has not received the DL/UL Individual Persistent A-MAP IE and the same DL/UL Persistent A-MAP IE can be transmitted again.”
No significant changes imposed to HARQ procedure and product
=> This can be the same as the procedure when the DROP received on transmitter side

6. Simulation Environments
Three mechanisms are compared
Tri-State HARQ feedback
Two-State HARQ feedback with buffer constraint
Two-State HARQ feedback without buffer constraint
Simulation Environments
Each HARQ burst has 4800 bits
Maximum 8 HARQ processes
Maximum 4 successful transmissions
HARQ buffer ranges from 10K to 80K soft bits
Round trip delay=20ms
Peak rate= 1.92Mbps
No feedback error
PB 3km/hr, VA 30km/hr and 120km/hr
Aggregated buffer is applied

7. IR-HARQ with PB 3km/hr No CQI Report Error
Transmission rate increases by 2~10 times for tri-state HARQ mechanism and two-state HARQ mechanism without buffer constraint
No transmission occurs if HARQ soft buffer is insufficient
Only half of transmission rate occurs when 80K HARQ soft bits are on AMS side
Two-state HARQ mechanism introduces larger HARQ failure rate when HARQ buffer is insufficient

8. IR-HARQ with VA 30km/hr No CQI Report Error
Transmission rate increases by 2~10 times for tri-state HARQ mechanism and two-state HARQ mechanism without buffer constraint
No transmission occurs if HARQ soft buffer is insufficient
Only half of transmission rate occurs when 80K HARQ soft bits are on AMS side
Two-state HARQ mechanism introduces extremely larger HARQ failure rate when HARQ soft buffer is insufficient
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 1/3 of HARQ soft buffer (60K soft bits)

9. IR-HARQ with VA 120km/hr No CQI Report Error
Transmission rate increases by 2~10 times for tri-state HARQ mechanism and two-state HARQ mechanism without buffer constraint
Tri-state further provides throughput gain by 30% when there is only10K HARQ soft buffer
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 1/3 of HARQ soft buffer (60K soft bits)

10. Summary of Observations
Tri-state HARQ feedback sustains highest throughput for all range of HARQ soft buffer without degraded wireless transmission
Two-state HARQ feedback without buffer constraint renders high throughput but
Lose link reliability when only 1/3 HARQ soft buffer exists
Lose by 30% transmission rate to tri-state HARQ feedback when no sufficient HARQ buffer exists at high mobility scenario

11. Conclusion
Three objectives are accomplished by tri-state HARQ feedback
2~10 times throughput enhancement
1~5 USD per AMS chip cost reduction
Reliable wireless transmission is guaranteed
It highly increases the system utilization and throughput when scarce AMSs are located within a cell
No significant complexity imposed to MAC procedure

12. Text Proposal [Add the following subclause after 15.3.6.4.2.7]
Aggressive HARQ Feedback A-MAP IE includes two bits and corresponding value for HARQ ACK/NACK/DROP information is shown in Table XXX. If AHF-A-MAP IE has the 0b00, 0b01 or 0b10, it shall be interpreted as ACK information, NACK information and DROP information, respectively, where DROP indicates that HARQ soft buffer is insufficient to store the current transmission...
Table XXX—AHF-A-MAP-IE
Syntax
Size (bit)
Notes
AHF-A-MAP IE format {
AHF-A-MAP IE value 2
0b00 : ACK feedback info.
0b01 : NACK feedback info.
0b10: DROP feedback info.
0b11: Reserved }

13. APPENDIX

14. Overhead Clarification

15. Overhead issue
Tri-state feedback channel is only applied for aggressive HARQ transmission mode, e.g. long burst service
Less resource shared by other users
More concurrent HARQ feedback channels
Bi-state feedback channel is applied for normal HARQ transmission mode, e.g. VoIP
Configuration example: 4 LRUs is configured for UL feedback channels
Tri-State HARQ feedback :
24 tri-state HARQ feedbacks (2 LRU)+36 1-bit HARQ feedbacks (2LRU)
Transmitting large packet (≧50Kbits) with limited overhead is reasonable
Nice-State two channel HARQ feedbacks:
36 tri-state HARQ feedbacks (2LRU)+36 1-bit HARQ feedbacks (2LRU)
Transmitting more HARQ processes to increase throughput is reasonable

16. An Example of Overhead Calculation
96 LRU per 20MHz
Downlink
500Kbps per 5ms frame
16 concurrent HARQ processes per 5ms
31250 bps per HARQ process
16 HARQ feedbacks per 5ms
16 Tri-State feedback occupies 4/3 LRU => 2LRU = 2.08% per UL subframe
Transmission (bits)/HARQ overhead (LRU) > 250K bits/LRU (high efficiency)
8 concurrent HARQ processes per 5ms
62500 bps per HARQ process
8 HARQ feedbacks per 5ms
8 Tri-State feedback occupies 2/3 LRU => 1LRU = 1.04% per UL subframe
Transmission (bits)/HARQ overhead (LRU) > 500K bits/ LRU (high efficiency)
VoIP:
26Kbps per user and 18 concurrent users
520bits per 20ms frame
18 concurrent users share one LRU for HARQ feedback (Intel, Samsung, LGe,…etc)
Transmission (bits)/HARQ overhead (LRU)= 9.36K bits/LRU (Low efficiency)
Feedback overhead is very minor for high throughput transmission

17. AGGRESSIVE IR-HARQ TRANSMISSION WITH 3DB CQI REPORT ERROR

18. IR-HARQ with PB 3km/hr 3dB CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism and two-state HARQ mechanism without buffer constraint
At high SNR, aggressive HARQ mechanism provides more transmission rate
Tri-state HARQ mechanism further provides throughput gain when buffer is insufficient
Two-state HARQ mechanism introduces large HARQ failure rate when Buffer is insufficient

19. IR-HARQ with VA 30km/hr 3dB CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Aggressive HARQ mechanism increases more throughput when SNR is high
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits or SNR is below than 16dB
Two-state HARQ mechanism introduces less transmission rate due to high HARQ failure rate

20. IR-HARQ with VA 120km/hr 3dB CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Aggressive HARQ mechanism increases more throughput when SNR is high
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits or SNR is below than 16dB
Two-state HARQ mechanism introduces less transmission rate due to high HARQ failure rate

21. AGGRESSIVE CC-HARQ TRANSMISSION WITH NO CQI REPORT ERROR

22. CC-HARQ with PB 3km/hr No CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits
Link reliability significantly decreases due to highly correlated channel condition

23. CC-HARQ with VA 30km/hr No CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits
Tri-State HARQ mechanism provides better link quality

24. CC-HARQ with VA 120km/hr No CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits
Tri-State HARQ mechanism provides better link quality

25. AGGRESSIVE IR-HARQ TRANSMISSION WITH 3DB CQI REPORT ERROR

26. CC-HARQ with PB 3km/hr 3dB CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits
Link reliability significantly decreases due to highly correlated channel condition

27. CC-HARQ with VA 30km/hr 3dB CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits
Tri-State HARQ mechanism provides better link quality

28. CC-HARQ with VA 120km/hr 3dB CQI Report Error
Transmission rate increases by 2~8 times for tri-state HARQ mechanism
Two-state HARQ mechanism introduces large HARQ failure rate when HARQ buffer is below than 60K soft bits
Tri-State HARQ mechanism provides better link quality