Post on 24-Jan-2017
Establishing Radio Links at 60 GHz for Truck Platooning
Presentation by,Manigandan Sivasubramanian.
Supervised by,Dr. Ir. Peter Smulders. ( Internal )Ir. Jacco Van de Sluis. ( External - TNO)
OVERVIEW OF THE PRESENTATION :
Introduction
Motivation and Objective
Truck Platooning and ITS–G5
IEEE 802.11ad
Propagation Mechanisms
Experiments at 60 GHz
LOS and NLOS Measurements
Special Cases
Future works and Conclusion
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INTRODUCTION
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OBJECTIVE
“Communication plays one of the key role in truck platooning and this project aims to make it more reliable by testing IEEE 802.11ad as the secondary redundant radio link”.
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INTRODUCTION TO THE PROJECT
• TNO is an independent research company constantly looking
for new solutions.
• To complement their existing communication link for truck
platooning.
• For this purpose, IEEE 802.11ad is tested in this project.
• This will guarantee a safe and reliable communication.
• Channel propagation characteristics , large scale shadowing
effects are studied.
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TRUCK PLATOONING
• Truck platooning comprises of trucks equipped with state of art driving support
system following each other.
• CACC and/or ACC are technologies behind truck platooning.
• Platooning improves the traffic safety with zero reaction time.
• Lower fuel consumption and less Cemission.
• Communication between trucks is essential and ITS-G5 is used.
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VEHICULAR COMMUNICATION (DSRC) – ITS-G5
• ITS-G5 is European standard and use IEEE 802.11p amendment.
• It is for data-only systems and operate on radio frequencies in the 5.725 – 5.875 MHz
• Broadcasting feature and support for Cooperative ITS.• It support single hop and multi hop transmission.
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IEEE 802.11ad
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S.No Parameter Value1 Operating Frequency 60 GHz
2 Number of Channels 4 (each 2.16 GHz wide)
3 Channel Frequency 58.32 , 60.48 , 62.64, 64.80 GHz.
FEATURES OF IEEE 802.11ad
• Huge Bandwidth availability.
• Standard specifies a “fast session transfer” feature, enabling wireless devices to
seamlessly transition between 60 GHz and the legacy 2.4 GHz and 5 GHz bands.
• Support for MIMO , it defines a new directional communication scheme to cope
with increased attenuation called “Virtual” antenna sectors that discretize
antenna azimuth.
• MAC algorithms include TDMA, CSMA/CA and polling. Applications requiring
gigabits data rate will benefit.
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Fig : Nodes communicating overVirtual Antenna Sector
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RADIO WAVE PROPAGATION AND CHANNEL MODEL
• Reflection , Diffraction and Scattering mechanisms – they depend on
size of the object and propagation path.
• FREE – SPACE MODEL: (Assumes ideal propagation condition)
* *(
It obeys distance power law which is given by,
PL (d) = PL (do) + 10 n log (d/ do) (1)
Path Loss exponent is a measure of decay in signal power with distance
• TWO – RAY MODEL: (Oscillation in power level by constructive and
destructive combination)
• Models at UHF for decay of power , depends on environment and breakpoint distances.
• Beyond breakpoint distance , measured and free-space value do not agree.
• Multipath Channel Characteristics – path loss exponent and delay spread describes the
property of a channel. LOG-DISTANCE PATH LOSS MODEL :
• Fading : Another significant part of wireless communication design. Small scale fading
and large scale shadowing are two types.
• The effect of shadowing can be included in the distance power law (1) as
• Value of n and are derived by linearly fitting measured path loss over log-distance.
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RECEIVED POWER AND CHANNEL MODEL
PL (d) = PL (do) + 10 n log (d/ do) + X
CHANNEL MEASUREMENTS AND ANALYSIS
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Description of Environment and Measurements
• Storage Area• Parking lot
Devices and Antennas Used:
• Vubic PEM – 009 Transceivers• Agilent 60 GHz Received Power Sensor and Power Meter• Fan – beam Antenna with 16.5 dbiGain. • Pencil beam Antenna with 34 dbigain
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STORAGE AREA : FLOORPLAN AND RESULT
Environment Characteristics :
n = 2.3 ; σ = 2.4 ; L (do) [dB] = 36.0
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PARKING LOT: FLOORPLAN AND RESULT
Environment Characteristics :
n = 1.5 ; σ = 4.2 ; L (do) [dB] = 36.0
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NLOS MEASUREMENTS
Fig : Obstruction by Truck Scenario
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RECEIVED POWER – NLOS MEASUREMENTS
• The difference in power level between LOS and NLOS is only 13 dB.
• LOS with obstruction vehicle has less difference in their power level with LOSprobably because of asphalt road surface.
• Reflection of signals from road surface helps in signal propagation – this leads toexploration on alternative antenna placements.
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RECEIVED POWER – LOS WITH DIFFERENCE IN ANTENNA HEIGHTS
Fig : Illustration of Two-Ray Model
• This experiment shows effect of Tx and Rx antenna heights on propagation losses.
• ht = 1.10 meters , hr = 0.90 meters. Two Ray Model requires less interference.
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RECEIVED POWER – MEASURED AT A FIXED DISTANCE IN VARIOUS ANTENNA ANGLE
APPLICATION : TRANSMISSION OF I/Q SIGNALS
I/Q modulation is an efficient way to transfer information. Hence we made use of random binary digits as input and transmitted it by generating I/Q signals.
Equipment and software used :
• 60 GHz transceivers• Antennas Used : Fan-beam Antennas with 16.5 dB gain.• Rohde and Schwarz AMIQ (I/Q Signal generator)• Rohde and Schwarz SMIQ ( Carrier Signal Generator)• Rohde and Schwarz FSIQ (Signal Analyzer)
Environment: Experiments are conducted in the propagation and system integration lab of CWT/e Lab at TU/e.
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BLOCK DIAGRAM
• Trial 1: QPSK signal
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Symbol Rate: 4.096 MHzFilter: Root Cosine with roll off factor: 0.5Data Source: PRBS.Coding : None.
Transmission frequency: 58.32 GHz.Carrier Signal Generated at Rx : 500 MHz.Received Channel Power: -22 dBm.Received Signal to Noise Ratio : 5.47 dB.
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FUTURE WORKS AND
CONCLUSION
FUTURE WORKS
• Demonstration of High-definition video transmission at 60 GHz.
• Planning of experiments on the truck requires making the measurement
setup more user friendly thus enabling reproducible measurements.
• Experiments to test slow and fast fading effects .
• How asphalt road surface can be used for signal propagation if
the environment doesn’t have metallic objects.
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CONCLUSION AND SUMMARY
• Practical experiments show that the presence of
metallic objects in the environment help in signal
propagation.
• Path Loss Exponent between 2-3 implies that 60 GHz
signal propagation is not much affected by multipath .
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Environment L (do) [dB] n
Parking lot – LOS 36.0 1.5 4.2
Storage Area – LOS 36.0 2.3 2.4
Storage Area - NLOS 34.2 2.5 9.2
• Two-ray model shows that an apparent minor difference
in the model can make significant change in behavior of
radio propagation.
• The performance of communication even at NLOS path
differs only by 13 dB because of reflection.
• Asphalt road surface helps in reflection of signals even
when the LOS between transceivers are blocked, thus this
allow for exploration on alternative antenna placements.
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THANK YOU QUESTIONS ?
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APPENDIX : DSRC – TECHNICAL OVERVIEW (Features of ITS-g5)
CHALLENGES : Congestion Control Bandwidth Availability
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S.NO Parameters Value
1 Frequency Range 5.855 – 5.925 MHz
2 Channels Available 7 with 10 MHz each
3 Modulation BPSK, OFDM, QPSK, 256-QAM…
4 Data Rate 6,9,12,18,24 and 27 Mbps
5 Power Less than 2W (33dBm)*
6 Message Types CAM , DENM.
* - Can go up to 30 W (44.8dBm) for public safety applications on Control Channel
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APPENDIX : INTRODUCTION OF VEHICLE IN THE LOS :
This test was done to see howcommunication was affected when a vehicle is introduced in the propagation path.
• Truck platooning is a modern application aiming to provide safer and cleaner transportation.
• ITS G-5 is the envisioned communication protocol used for this purpose but has limited
bandwidth.
• IEEE 802.11ad is proposed to complement this existing link with additional link capacity.
• Theoretical study on various challenges that comes with IEEE 802.11ad have been studied.
Estimating Path Loss Exponent and Zero-mean Gaussian distributed random variable with
standard deviation Sigma.
- - - > (1)
Then sum of squared errors between measured and estimated values is given by
- - - > (2) ; J(n) = 0
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• Free-pace path loss :
FSPL =