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Doc.: IEEE 802.11-15/0705r1 Submission Control PHY Design for 40-50GHz Millimeter Wave Communication Systems Authors: May 2015 Slide 1Jianhan Liu, et.

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Presentation on theme: "Doc.: IEEE 802.11-15/0705r1 Submission Control PHY Design for 40-50GHz Millimeter Wave Communication Systems Authors: May 2015 Slide 1Jianhan Liu, et."— Presentation transcript:

1 doc.: IEEE 802.11-15/0705r1 Submission Control PHY Design for 40-50GHz Millimeter Wave Communication Systems Authors: May 2015 Slide 1Jianhan Liu, et. al. (MediaTek)

2 doc.: IEEE 802.11-15/0705r1 Submission Introduction Link budget analysis shows that beamforming is needed to support 10m NLOS[1] Discovery and beamforming training needs control PHY that works in low SNR environments This proposal designs a Control PHY with low implementation complexity and good performance May 2015 Slide 2Jianhan Liu, et. al. (MediaTek)

3 doc.: IEEE 802.11-15/0705r1 Submission Design Requirements on Control PHY[1] One side beamforming gain can be provided by sector level sweep –Gain is about 10*log10(N), N it the number of antenna, for example, using 8 antennas can get 6-9 dB –Note that receive antenna gain does not count Tx power increase. Assume 8dB Gain is provided by one side beamforming, than extra gain 8dB is needed for BPSK and LDPC ½ rate code. We need a low rate PHY that can operate at SNR: –-8+1.0=-7 dB. May 2015 Slide 3Jianhan Liu, et. al. (MediaTek)

4 doc.: IEEE 802.11-15/0705r1 Submission Control PHY Design May 2015 Slide 4Jianhan Liu, et. al. (MediaTek) –Control PHY Preamble still uses ZCZ sequences Easier for implementation since common preamble sequences for SC PHY and OFDM PHY [2] –Control PHY is only transmitted in 540MHz channel To get extra range and reduce the complexity –Control PHY Header and Data portion Modulation: BPSK with LDPC encoded Single Carrier (SC) with Spreading Spreading factor is changeable for flexible designs and different spectrum efficiency.

5 doc.: IEEE 802.11-15/0705r1 Submission Spreading with Barker Sequences Spreading using Barker Sequences Barker sequence is a finite sequence of N values of +1 and −1 with ideal correlation property The chosen spreading sequences are in read and filled with blue color. Barker Sequence has the lowest sidelobe level ratio among all binary sequences Spreading with factor 13 provides 11dB SNR enhancement May 2015 Slide 5Jianhan Liu, et. al. (MediaTek) LengthCodesSidelobe level ratioSNR Gain 2+1 −1+1 −6 dB3dB 3+1 +1 −1−9.5 dB4.7dB 4+1 +1 −1 +1+1 +1 +1 −1−12 dB6dB 5+1 +1 +1 −1 +1−14 dB7dB 7+1 +1 +1 −1 −1 +1 −1−16.9 dB8.4dB 11+1 +1 +1 −1 −1 −1 +1 −1 −1 +1 −1−20.8 dB10.4dB 13+1 +1 +1 +1 +1 −1 −1 +1 +1 −1 +1 −1 +1−22.3 dB11.1dB

6 doc.: IEEE 802.11-15/0705r1 Submission Signaling on spreading factor Spreading factor signaling information can be conveyed using a field control PHY header –PHY header is spread with barker sequence 13 and with fixed encoding schemes. May 2015 Slide 6Jianhan Liu, et. al. (MediaTek) Field nameNumber of BitsStarting BitDescription Reserved10 Set to 0 (differential detector initialization). Scrambler Initialization41 Bits of the initial scrambler state Length105 Number of data octets in the PSDU. Range 14-1023. Packet Type115 TRN packet type Training Length 516 Length of the training field. Turnaround 121 Set to 1 if the STA is transmitting a packet during an SP or TXOP. Spreading Factor 222 Set to 0: spreading by 13 Set to 1: spreading by 7 Set to 2: spreading by 4 Set to 3: no spreading HCS 1624 Header Check sequence.

7 doc.: IEEE 802.11-15/0705r1 Submission Simulation Settings LDPC code rate ½ BPSK modulation Spreading factor 4, 5, 7, 11, 13 Packet size 42 bytes (336 bits) Real Channel Estimation based on Channel Estimation Sequences using ZCZ 256 sequences AWGN, Exp 4ns, Exp 10 ns, Exp 20 ns channels May 2015 Slide 7Jianhan Liu, et. al. (MediaTek)

8 doc.: IEEE 802.11-15/0705r1 Submission PER in AWGN Channels  With Spreading 13, system can work at SNR less than -11dB, which is good enough for an AP with 4 TX antennas. SFSNR (dB) @10 -1 PER 13-11.2 11-10.6 7-9.1 5-7.9 4-7.0 PER May 2015 Slide 8Jianhan Liu, et. al. (MediaTek)

9 doc.: IEEE 802.11-15/0705r1 Submission BLER in Exp 4ns Channels SFSNR (dB) @10 -1 PER 13-10.6 11-9.9 7-8.2 5-6.7 4-5.2 PER May 2015 Slide 9Jianhan Liu, et. al. (MediaTek)

10 doc.: IEEE 802.11-15/0705r1 Submission BLER in Exp 10ns Channels SFSNR (dB) @10 -1 PER 13-9.7 11-9.2 7-7.3 5-5.3 4-3.2 PER May 2015 Slide 10Jianhan Liu, et. al. (MediaTek)

11 doc.: IEEE 802.11-15/0705r1 Submission BLER in Exp 20ns Channels SFSNR (dB) @10 -1 PER 13-8.1 11-7.5 7-5.6 5-3.1 4-0.2 PER May 2015 Slide 11Jianhan Liu, et. al. (MediaTek)

12 doc.: IEEE 802.11-15/0705r1 Submission Performance Summary SNR @ 10 -1 PER SFAWGNExp 4nsExp 10 nsExp 20ns 13-11.2-10.6-9.7-8.1 11-10.6-9.9-9.2-7.5 7-9.1-8.2-7.3-5.6 5-7.9-6.7-5.3-3.1 4-7.0-5.2-3.2-0.2 May 2015 Slide 12Jianhan Liu, et. al. (MediaTek)

13 doc.: IEEE 802.11-15/0705r1 Submission Summary Link Budget analysis shows that a control PHY that works in low SNR regime is required. We propose a control PHY design with low implementation cost and good PER performance. May 2015 Slide 13Jianhan Liu, et. al. (MediaTek)

14 doc.: IEEE 802.11-15/0705r1 Submission References [1] WPAN-PG4-T-14-036-00 Mediatek Introduction to Beamforming Protocols for 40-50GHz [2] Complete-specification-proposal-IEEE-802.11aj(45GHz)_v0.1.1 May 2015 Slide 14Jianhan Liu, et. al. (MediaTek)

15 doc.: IEEE 802.11-15/0705r1 Submission BACKUP May 2015 Slide 15Jianhan Liu, et. al. (MediaTek)

16 doc.: IEEE 802.11-15/0705r1 Submission Link Budget for NLOS case Extra gain needed SNR requirement is 1.0 dB for BPSK, ½ rate code Extra Gain Needed: 20*log10(d)-(Rx_SNR-required_SNR)=16dB May 2015 Slide 16Jianhan Liu, et. al. (MediaTek) Tx power (dBm)10 Tx Antenna Gain0 Center Frequency (GHz)45 Propogation Loss at 1m (dB)65.56425 Shawdowing+link margin10 RX antenna Gain0 Receiver Signal Strength-65.5643 Rx Noise Figure (dB)10 Immeplentaion loss (dB)2 BW (GHz)1 Noise Floor-84 RX SNR (dB)6.43575 SNR BPSK, LDPC 1/21.0 Distance (m)1.573213 extra gain needed for 10m NLOS (dB)16.06425

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