1. Synchronized Ranging Structure for IEEE P802.16m/D1
Document Number: C80216m-1945
Date Submitted:
Source:
Pei-Kai Liao, Yih-Shen Chen and Paul Cheng
MediaTek Inc.
Zheng Yan-Xiu
ITRI
Venue: IEEE Session #63, Jeju, Korea
Base Contribution: This is base contribution
Re: D1 comment
Purpose: For TGm members’ discussion and approval
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2. Design Considerations
Low overhead
Meet the latency requirement with low overhead
High timing estimation accuracy
Meet the required timing accuracy of WiMAX system
High detection rate
Support up to P-user transmission simultaneously
Able to detect the transmitted code sequences by K users successfully
P depends on the system load and user arrival rate
Performance requirements
Miss detection rate ≦ 1%
False alarm rate ≦ 0.1%
Timing estimation error ≦ ± (Tb/32)/4 samples ( us)
≦ ± 4 samples when the channel bandwidth is 5 MHz
≦ ± 8 samples when the channel bandwidth is 10 MHz
≦ ± 16 samples when the channel bandwidth is 20 MHz

3. Proposed Synchronous Ranging Channel Structure (1/5)
Ranging Channel Structure for Synchronized AMSs
UL ranging channel for synchronized AMSs is used for periodic ranging in macrocells; initial ranging, handover ranging and periodic ranging in femtocells
RCP length is equal to normal CP and RP length is equal to Tb
It occupies 72 subcarriers by K OFDM symbol time
For femtocells, K = 1 and the rest of subcarriers are used for data transmission (5-symbol LRUs)
Ranging Preamble Codes
Frequency-domain cyclic padded Zadoff-Chu code is applied
Code #1:
Adopted by current AWD
Code #2:
Suggested modification

4. Proposed Synchronous Ranging Channel Structure (2/5)
Suggested code sequence configuration
Code #2 is suggested
Technical reason is described in the Appendix
The number of cyclic shifted codes per ZC root index for code #2 is shown as follows
index 1 2 3 M 4 8

5. Proposed Synchronous Ranging Channel Structure (3/5)
Allocation of synchronous ranging channel
Idle-to-active latency requirement in SRD: 100 ms
Handover interruption time requirement in SRD
Intra-frequency: 27.5 ms
Inter-frequency: 40 ms (within a spectrum band), 60 ms (between spectrum bands)
The requirement applied to initial ranging, handover ranging in femtocells so it has to be allocated much more frequent in femtocells than in macrocells
Shorter allocation periodicity; larger overhead
Proposed approach can reduce the overhead in femtocells
Synchronous ranging channel allocations for macrocell and femtocell can be separate or co-located

6. Proposed Synchronous Ranging Channel Structure (4/5)
1 bit to signal two formats in SFH
Format
Multiplexing Mode
TDM/CDM among cells: 72 subcarriers × 3 OFDM symbols per ranging channel allocation
Cells with mod(Cell_ID, 2)=q utilize (3×q+1)th ~ (3×q+3)th OFDM symbol of the subframe for ranging channel allocation. 1
CDM among cells: two duplicate 72 subcarriers × 3 OFDM symbols per ranging channel allocation
All cell utilizes 6 OFDM symbols of the subframe for the ranging channel allocation.

7. Proposed Synchronous Ranging Channel Structure (5/5)
Suggested configuration of time-domain allocation by SFH
For macrocells, configuration 2 and 3 are applied
For femtocells, configuration 0 and 1 are applied
Configurations
The subframe allocating Ranging channel
OSFth UL subframe in every frame 1
OSFth UL subframes in the first frame in every superframe 2
OSFth UL subframe in the first frame in every 8 superframe 3
OSFth UL subframe of the first frame in every 16 superframes

8. Format #0 TDM/CDM among cells:
One ranging opportunity occupies Nsc subcarriers by K OFDM symbols
Nsc=72, K=3
72 subcarriers × 3 OFDM symbols per ranging channel allocation
One subframe time is allocated for synchrounous ranging channel in each allocation
One cell utilizes only 1 opportunity for periodic ranging, and the rest of ranging opportunities are utilized by other cells
Cells with mod(Cell_ID, 2)=q utilize (3×q+1)th ~ (3×q+3)th OFDM symbol of the subframe for ranging channel allocation

9. Format #1 CDM among cells:
One ranging opportunity occupies Nsc subcarriers by K OFDM symbols
Nsc=72, K=6
Two duplicate 72 subcarriers × 3 OFDM symbols per ranging channel allocation
One subframe time is allocated for synchrounous ranging channel in each allocation
K=6, there is only one ranging opportunity for one macrocell
All cell utilizes 6 OFDM symbols of the subframe for the ranging channel allocation

10. Ranging Channel Allocation (1/3)
Separate allocations for macrocells and femtocells
Ranging channel allocations for femtocells are more frequency than those for macrocells
The allocations are separate for macrocells and femtocells
The size of allocations for macrocells and femtocells can be the same or different

11. Ranging Channel Allocation (2/3)
Collocated allocation for femtocells and macrocells
Ranging channel allocations for femtocells have the same periodicity as those for macrocells
All allocations are shared by macrocells and femtocells
The size of allocations for macrocells and femtocells can be the same or different

12. Ranging Channel Allocation (3/3)
Partially collocated allocation for femtocells and macrocells
Ranging channel allocations for femtocells are more frequency than those for macrocells
Some allocations are shared by macrocells and femtocells and others are for femtocells only
The size of allocations for macrocells and femtocells can be the same or different

13. Appendix

14. Code Sequence Generation
How many codes can be generated by circular-shift per root code to meet the timing estimation requirement?
Ncs×(NFFT/NRP) >> 2×(maximal timing error)
floor(71/8)×(512/71) = >> 2×5 = 10
M = 8 can meet the requirement
It is suggested to generate up to 8 code sequences per root code by circular-shift
Total up to 70×8=560 code sequences

15. Time-Domain Property of Code #2

16. Size of Synchronous Ranging Channel
Three candidate structures
6×6, 18×6, 72×1
Timing estimation performance depends on the time-domain autocorrelation property of the designed code sequence
If ZC code is applied, its time-domain autocorrelation property depends on the ratio of the number of occupied subcarriers over total subcarriers
NFFT/Nrang
6×6: NFFT/Nrang = 512/6 = >> 4 (samples)
18×6: NFFT/Nrang = 512/18 = >> 4 (samples)
72×1: NFFT/Nrang = 512/72 = 7.11 ～ 4 (samples)
72×1 structure can provide better timing estimation performance, compared to the other two candidates
There is no need to consider 144×1 structure since 72×1 structure can already meet the requirement
It is suggested to adopt 72×1 structure for synchronous ranging channel

17. Auto-correlation Property of Candidate Structures

18. Simulation Parameters
Carrier frequency: 2.5 GHz
Total bandwidth: 5 MHz
FFT size: 512
Sampling rate: 5.6 MHz
CP length: 1/8
Antenna configuration: 1 Tx, 2 Rx
Channel model: Wideband ITU-PB 3 km/hr, Wideband ITU-VA 120 km/hr
Code selection: random selection for the code set
Timing error: random within ±8 samples
Frequency error: random within 2% subcarrier spacing
Ranging detector: correlation detector

19. Timing Estimation Performance

20. Detection Performance