Doc.: IEEE 802.15-15-0667-00-hrrc Submission September 2015 Junhyeong Kim, ETRISlide 1 Project: IEEE...
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Transcript of Doc.: IEEE 802.15-15-0667-00-hrrc Submission September 2015 Junhyeong Kim, ETRISlide 1 Project: IEEE...
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
September 2015
Junhyeong Kim, ETRISlide 1
Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs)
Submission Title: [A Study on mmWave Beamforming for High-Speed Train Communication]Date Submitted: [11 September, 2015]Source: [Junhyeong Kim, Bing Hui, Hee-Sang Chung, JunHwan Lee] Company [ETRI]Address [218 Gajeong-ro, Yuseong-gu, Daejeon, 305-700, KOREA]Voice:[+82-42-860-6239], FAX: [+82-42-860-6732], E-Mail:[[email protected]]Abstract: [A Study on mmWave Beamforming for High-Speed Train Communication]
Purpose: [For discussion]Notice: This document has been prepared to assist the IEEE P802.15. 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 P802.15.
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Contents• Introduction• Network Structure• Beamforming• Simulation• Conclusions• References
Slide 2
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Introduction• Hierarchical two-hop network for fast moving vehicles
– Mobile wireless backhaul link• High rate rail communications Interest Group (IG HRRC) : a multi-gigabit-per-sec-
ond mobile wireless backhaul supporting high-mobility up to 500km/h– Access link
• Small cell (Wi-Fi and femto cell)
Slide 3
DU
GW
Public Internet
RU
GW : GatewayDU : Digital UnitRU : Radio UnitTE : Terminal Equipment
RU
TE
Backhaul LinkmmWave
Backhaul LinkmmWave
Access Link(inside vehicle)
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Introduction• Various technical challenges and potential solutions
– Capacity improvement• Millimeter-wave due to its vast amount of underutilized spectrum• MIMO techniques (polarized antenna)
– Path loss and atmospheric attenuation of millimeter-wave• coverage improvement by using beam-forming technique
– Inter-carrier interference (ICI) by Doppler effect• Proper sub-carrier spacing design for OFDM• Millimeter-wave beam-forming techniques Doppler frequency shift in the fre-
quency domain can be simply overcome by automatic frequency control (AFC)
Slide 4
ETRI’s approach to physical layer design
Mobile Wireless Backhaul Link(Outside Vehicle)
OFDM based on mmWave Beam-forming (2-link multi-flow)
Data throughput (DL) 2 Gbps using 500-MHz bandwidth
Spectral efficiency 4 bps/Hz
Mobility Support 500 km/h
User Access Link (Inside Vehicle) WiFi or Femto
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Network Structure• Millimeter-wave beamforming for HST communication
– Dual link multi-flow : same radio resources (time and fre-quency) are assigned to both links
Slide 5
zy
x(0, 0, 0)
fixed BF
adaptive BF
optical fiber
X2 interface
Public Internet
... ...
GW
DU #d+1DU #d
D-RU #mD-RU #m-1 D-RU #m+2D-RU #m+1 D-RU #m+4D-RU #m+3
direction of movement
T-RU #1 T-RU #2
z'
y'x'
DRUd DRUd
TRUd
DRU trackd
DRUh
TRUh
(0, dDRU-track, hDRU) (dDRU, dDRU-track, hDRU) (2 dDRU, dDRU-track, hDRU)
HST : (0, 0, 0) (x, 0, 0), T-RU #1 (-dTRU/2, 0, hTRU) (-dTRU/2+x, 0, hTRU)T-RU #2 (dTRU/2, 0, hTRU) (dTRU/2+x, 0, hTRU)
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Beamforming• 3D beam radiation pattern
– Horizontal and vertical beam width (3dB) : approximately 8 degrees
– Maximum beamforming gain : 21.58 dBi
Slide 6
-200 -150 -100 -50 0 50 100 150 200-40
-30
-20
-10
0
10
20
30Beam Radiation Pattern
Degree ()
Gai
n (d
Bi)
=0
=90z
yx
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Beamforming• Adaptive BF : require automatic tracking of signals of moving
targets by continuously updating their parameters based on the received signals– Control the beam direction with an accuracy 1˚– Beam radiation pattern remains unchanged during beam steering
Slide 7
zy
x(0, 0, 0)
optical fiber
X2 interface
Public Internet
... ...
GW
DU #d+1DU #d
direction of movement
z'
y'x'
DRUd DRUd
TRUd
DRU trackd
HST : (0, 0, 0) (x, 0, 0), T-RU #1 (-dTRU/2, 0, hTRU) (-dTRU/2+x, 0, hTRU)T-RU #2 (dTRU/2, 0, hTRU) (dTRU/2+x, 0, hTRU)
(dDRU, dDRU-track, hDRU) (2 dDRU, dDRU-track, hDRU)
DRUh(0, dDRU-track, hDRU) D-RU #mD-RU #m-1 D-RU #m+2D-RU #m+1 D-RU #m+4D-RU #m+3
TRUh
T-RU #1 T-RU #2
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Beamforming• Fixed BF : BF parameters are fixed
– In the case of TX, the beam direction of m-th D-RU and m+1-th D-RU is (dRU/2, 0, 0) and the beam direction of m+2-th D-RU and m+3-th D-RU is (3∙dRU/2, 0, 0)
– In the case of RX, the beam directions of T-RU 1 and T-RU 2 are simply set to direct in the negative and positive direction of the x-axis respectively
Slide 8
zy
x(0, 0, 0)
optical fiber
X2 interface
Public Internet
... ...
GW
DU #d+1DU #d
direction of movement
z'
y'x'
DRUd DRUd
TRUd
DRU trackd
HST : (0, 0, 0) (x, 0, 0), T-RU #1 (-dTRU/2, 0, hTRU) (-dTRU/2+x, 0, hTRU)T-RU #2 (dTRU/2, 0, hTRU) (dTRU/2+x, 0, hTRU)
(dDRU, dDRU-track, hDRU) (2 dDRU, dDRU-track, hDRU)
DRUh(0, dDRU-track, hDRU) D-RU #mD-RU #m-1 D-RU #m+2D-RU #m+1 D-RU #m+4D-RU #m+3
TRUh
T-RU #1 T-RU #2
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Simulation• Simulation scenarios
– adaptive BF (BS) + adaptive BF (TE)– fixed BF (BS) + fixed BF (TE)– fixed BF (BS) + adaptive BF (TE)
• Performance evaluation– received signal quality
• , – =
Slide 9
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Simulation• Major parameters
Slide 10
Parameters ValuesCarrier frequency fc = 32 GHzSystem bandwidth W = 125 MHzTransmit power PTX,dBm = 20 dBm
Free space path loss [1]PLdB = 92.4 + 20 log fc,GHz + 20 log dkm (dB)
Noise figure NF,dB = 8 dBD-RU height hDRU = 10 mT-RU height hTRU = 3 mDistance between adjacent D-RUs dDRU = 1000 m
Distance between adjacent T-RUs dTRU = 200 m
Distance betweenRailway track and D-RUs
dDRU-track {10, 50, 100, 150} m
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Simulation• Simulation results : received signal quality
– As the HST moves far away from the D-RU, the effect of adaptive BF is negligible whereas it is important to use adaptive BF if the T-RU is close to D-RU
Slide 11
0 100 200 300 400 500 600 700 800 900 1000-60
-40
-20
0
20
40
60SINR of Received Signal
HST Location (m)
SIN
R (d
B)
TRU #1 (FXD TX BF, FXD RX BF)TRU #2 (FXD TX BF, FXD RX BF)TRU #1 (ADP TX BF, ADP RX BF)TRU #2 (ADP TX BF, ADP RX BF)TRU #1 (FXD TX BF, ADP RX BF)TRU #2 (FXD TX BF, ADP RX BF)
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Simulation• Simulation results : received signal quality
– Received signal strength < 2 dB in the HST location from 200m to 800m• If the T-RUs are placed sufficiently far away from each other, inter-D-RU
interference at each T-RU is significantly reduced with a properly sharp beam pattern designed for both TX and RX side
Slide 12
0 100 200 300 400 500 600 700 800 900 10000
2
4
6
8
10
12
14
16
18Degradation of Received Signal Strength
HST Location (m)
Deg
rada
tion
(dB
)
TRU #1 (FXD TX BF, FXD RX BF)TRU #2 (FXD TX BF, FXD RX BF)TRU #1 (ADP TX BF, ADP RX BF)TRU #2 (ADP TX BF, ADP RX BF)TRU #1 (FXD TX BF, ADP RX BF)TRU #2 (FXD TX BF, ADP RX BF)
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Simulation• Simulation results : AoD, AoA
– Both vary according to – : distance between DRU and railway track
Slide 13
0 100 200 300 400 500 600 700 800 900 10000
50
100
150
200Angle of Departure (Transmit Beamforming)
HST Location (m)
(D
egre
e)
0 100 200 300 400 500 600 700 800 900 10000
50
100
150
200Angle of Arrival (Receive Beamforming)
HST Location (m)
(D
egre
e)
dDRU-track=10m
dDRU-track=50m
dDRU-track=100m
dDRU-track=150m
• AoD : Angle of Departure(transmit beamforming)
• AoA : Angle of Arrival(receive beamforming)
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Simulation• Simulation results
Slide 14
0 100 200 300 400 500 600 700 800 900 10000
50
100
150
200Zenith Angle ()
HST Location (m)
Ang
le (D
egre
e)
AoD (TX BF)AoA (RX BF)
0 100 200 300 400 500 600 700 800 900 1000-100
0
100
200Azimuth Angle ()
HST Location (m)
Ang
le (
Deg
ree)
0 2 4 6 8 10 12 14 16 18 20105
110
115
120
HST moves from (94,0,0) meters to (104,0,0) metersVelocity of HST = 400 km/h
Zenith Angle ()
Elapsed Time (msec)A
ngle
(D
egre
e)
AoDAoAAoD (round-off)AoA (round-off)
0 2 4 6 8 10 12 14 16 18 20-20
0
20
40
60Azimuth Angle ()
Elapsed Time (msec)
Ang
le (D
egre
e)
• AoD : Angle of Departure(transmit beamforming)
• AoA : Angle of Arrival(receive beamforming)
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
Conclusions• Different BF schemes are appropriate for different
HST location • The fixed BF can achieve very similar performance to
that of adaptive BF in most of time– giving a valuable insight into designing the mmWave BF
based HST communication system from feasibility and im-plementation perspective
• As future works, it is worth to study the performance of adaptive BF in the presence of calibration error and the HST communication system in various envi-ronments including the case of HST running along the curved line.
Slide 15
September 2015
doc.: IEEE 802.15-15-0667-00-hrrc
Submission
Junhyeong Kim, ETRI
References1. ITU-R P.525-2, “Calculation of free-space attenua-
tion”
Slide 16
September 2015