Powerline Communications: Channel Characterization and Modem Design Yangpo Gao Helsinki University of Technology
Powerline Communications: Channel Characterization and Modem Design 2 Yangpo Gao, Thesis Contents Table of Contents Introduction PLC Technology Background Channel Measurement and Modeling Disturbance over PLC DMT Based PLC Modem Design Conclusion Reference This thesis is part of project “ PLC controlled LEDs for general lighting system”, which is sponsored by TEKES
Introduction
Powerline Communications: Channel Characterization and Modem Design 4 Yangpo Gao, History of PLC and Motivation of Thesis What is PLC PLC – Powerline Communications Using powerline as transmission medium for data communication History of PLC From high voltage (HV) low voltage (LV) Low data rate high data rate Control application multimedia data applications Motivation Cheap “the last mile” solution However, worse channel than other wired network Channel characterization reliable communications
PLC Technology Background
Powerline Communications: Channel Characterization and Modem Design 6 Yangpo Gao, PLC Technologies Three network levels High voltage (110–380 kV) Medium voltage (10–30 kV) Low voltage (230/400 V, in the USA 110 V) (my thesis range) Efficient coupling Inductive coupling Conductive coupling Modulation and error correction OFDM, DMT CDMA FEC
Powerline Communications: Channel Characterization and Modem Design 7 Yangpo Gao, EMC Issues EMC --Electromagnetic compatibility The ability of a device or system to function satisfactorily in its electromagnetic environment without introducing intolerable electromagnetic disturbances in the form of interferences to any other system in that environment, even to itself.
Powerline Communications: Channel Characterization and Modem Design 8 Yangpo Gao, Standardizations PLC standardization bodies International Regional National
Channel Measurement and Modeling
Powerline Communications: Channel Characterization and Modem Design 10 Yangpo Gao, Transmission Line Theory A piece of mains cable can be modeled as following figure R : resistance. L : inductance. G : conductance C : capacitance Attenuation constant phase constant Characteristic impedance Propagation constant
Powerline Communications: Channel Characterization and Modem Design 11 Yangpo Gao, Channel Measurement Setup Equipment: Network Analyzer (NA) Coupling Circuit Coupling circuit Conductive coupling High pass filter Galvanic isolation Over Voltage protection
Powerline Communications: Channel Characterization and Modem Design 12 Yangpo Gao, Rapid fluctuation caused by impedance mismatch Maximum of 4 dB attenuation 100 MHz Cable transversal PLC Cable Measurements Cable TypeSize (mm 2 ) Vulcanize rubber cable (three-wire)0.75 Vulcanize rubber cable (three-wire)1 PVC/PVC cable (three-wire)0.75 PVC/PVC cable (two-wire)0.5
Powerline Communications: Channel Characterization and Modem Design 13 Yangpo Gao, PLC Channel Measurements Scenario 1: Internet access and distribution Scenario 2: Home networking Scenario 1: Network topology is known, or easy to estimate. Channel is simple, and has few multipath components Scenario 2: Network topology is unknown or it is hard to define. Channel acts as black box. A lot of multipath components
Powerline Communications: Channel Characterization and Modem Design 14 Yangpo Gao, Channel Responses Frequency Domain Time Domain Scenario 1 Scenario 2
Powerline Communications: Channel Characterization and Modem Design 15 Yangpo Gao, PLC Channel Modeling According to PLC channel multipath phenomenon, channel can be modeled as:
Disturbance over PLC
Powerline Communications: Channel Characterization and Modem Design 17 Yangpo Gao, PLC Noise Noise Classification: Colored background noise Narrowband noise Periodic impulsive noise, asynchronous to the main frequency Periodic impulsive noise, noise, synchronous to the main frequency Asynchronous impulsive noise Our concentration Colored background noise Asynchronous impulsive noise
Powerline Communications: Channel Characterization and Modem Design 18 Yangpo Gao, Noise Measurement setup Equipment: Oscilloscope Spectrum Analyzer Coupler
Powerline Communications: Channel Characterization and Modem Design 19 Yangpo Gao, Colored Background Noise Quasi-Static behavior Statistic information is extracted in table Can be modeled as: sbc Max Min Average
Powerline Communications: Channel Characterization and Modem Design 20 Yangpo Gao, Random Impulsive Noise Caused by frequency bursts generated by electrical devices connected to the powerline. Statistic information is extracted
Powerline Communications: Channel Characterization and Modem Design 21 Yangpo Gao, Other Disturbance NEXT (Near End crosstalk) FEXT (Far End crosstalk). NEXT Formation FEXT Formation
DMT Based PLC Modem Design
Powerline Communications: Channel Characterization and Modem Design 23 Yangpo Gao, DMT Technology Discrete Multi-tone Modulation (DMT) Advantages: Multicarrier technology – combat frequency selective fading Dynamic bit loading based on SNR – efficient spectrum utilization High channel capacity
Powerline Communications: Channel Characterization and Modem Design 24 Yangpo Gao, DMT Based PLC Modem Design Simulation environment: MATLAB SimuLink MATLAB DSP Blockset Simulated channel response Expected result Bit Error Rate (BER)
Powerline Communications: Channel Characterization and Modem Design 25 Yangpo Gao, Simulation and Performance Optimized bit loading algorithm Signal spectrum before PLC channel Signal spectrum after PLC channel Modem performance PLC vs AWGN
Publications Related to My Thesis
Powerline Communications: Channel Characterization and Modem Design 27 Yangpo Gao, Publications More information can be found in my publications: “Channel modeling and modem design for broadband power line communications”, Proceeding of ISPLC 2004, April, Spain “Broadband characterization of indoor powerline channel”, Proceeding of ISPLC 2004, April, Spain “Broadband Characterization of Indoor Powerline Channel and Its Capacity Consideration”, Proceeding of ICC 2005, May, Korea
Any Questions? Thank You!