SC LOS/NLOS Channel Measurements

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Presentation transcript:

SC LOS/NLOS Channel Measurements September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 SC LOS/NLOS Channel Measurements Date: 2015-03-08 Authors: Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Motivation and purpose September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Motivation and purpose In this presentation we present LOS/NLOS channel measurements in cubical environment We would like to learn the existing channel looking forward to 11ay Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Setup Test have been performed using two commercial Dell PCs running Linux Both recording HW and antennas are the same as provided in the product (32 antenna elements per array). Beamforming was done by the FW in the product itself. No interference during the measurement Test have been done with high SNR (EIRP>= 19 dBm) Channel estimation is based on the Golay correlators in the modem, running at 1.76GHz Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Environment Two Laptops March 2015 September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Environment Two Laptops Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 1 LOS case Reflection is stronger than LOS due to rotation September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 1 LOS case Reflection is stronger than LOS due to rotation Trms=2.5 ns (AP), 1.9 (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 2 LOS case 1 meter, boresight to boresight September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 2 LOS case 1 meter, boresight to boresight Trms=2.4 ns (AP), 1.3 ns (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 3 LOS case <1m, boresight to backside. LOS clearly seen. September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 3 LOS case <1m, boresight to backside. LOS clearly seen. Trms=1 ns (AP), 1 ns (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 4 NLOS case 1 meter, boresight to boresight. September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 4 NLOS case 1 meter, boresight to boresight. Trms=1.8 ns (AP), 1.8 ns (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 5 LOS case AP on the wall, PC on cubicle. LOS is available September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 5 LOS case AP on the wall, PC on cubicle. LOS is available Trms=3.5-4 ns (AP) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 6 LOS case AP on the wall, PC on corridor LOS is available September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 6 LOS case AP on the wall, PC on corridor LOS is available Trms=1 ns (AP) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 7 LOS case AP on the wall, PC on corridor (far) September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 7 LOS case AP on the wall, PC on corridor (far) LOS is available Trms=1.6-2 ns (AP), 2-2.6 (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 8 LOS case AP on the ceiling, PC in cubic LOS is available September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 8 LOS case AP on the ceiling, PC in cubic LOS is available Trms=1.5-1.2 ns (AP), 2.1-2.3 (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 9 LOS case AP on the ceiling, PC in cubic September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 9 LOS case AP on the ceiling, PC in cubic LOS is available, boresight to boresight Trms=1.7-3.5ns (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 10 LOS case AP on the ceiling, PC in corridor September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 10 LOS case AP on the ceiling, PC in corridor LOS is available, boresight to boresight Trms=3-4 ns (STA) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 11 LOS case AP on the ceiling, PC in cubic below September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 11 LOS case AP on the ceiling, PC in cubic below LOS is available Trms=1.8 ns (STA), 1.4-1.8 ns (AP) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Position 12 LOS case AP on the ceiling, PC is person height September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Position 12 LOS case AP on the ceiling, PC is person height LOS is available Trms=1.5-2 ns (STA), 1.8 ns (AP) Far from ladder Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

Summary Measured Trms range: 1-4 ns September 2014 doc.: IEEE 802.11-14/1202r0 March 2015 Summary Measured Trms range: 1-4 ns MMSE EQ degradation is expected to be 3-11 dB for LOS channels The NLOS channel tested had the same EQ degradation and the same delay spread (Trms) as the LOS channels (Perhaps due to diffraction taking the lead) Alecsander Eitan, Qualcomm Amichai Sanderovich, Qualcomm

March 2015 Backup Alecsander Eitan, Qualcomm

March 2015 Position 1 Position 2 Alecsander Eitan, Qualcomm

March 2015 Position 3 Position 4 Alecsander Eitan, Qualcomm

March 2015 Position 5 Position 6 Alecsander Eitan, Qualcomm

March 2015 Position 7 Position 8 Alecsander Eitan, Qualcomm

March 2015 Position 9 Position 10 Alecsander Eitan, Qualcomm

March 2015 Position 11 Position 12 Alecsander Eitan, Qualcomm