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E225C – Lecture 16 OFDM Introduction EE225C
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Multipath can be described in two domains: time and frequency. time Sinusoidal signal as input time Sinusoidal signal as output f Frequency response Time domain: Impulse response Frequency domain: Frequency response time Impulse response time
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Modulation techniques: monocarrier vs. multicarrier To improve the spectral efficiency: To use orthogonal carriers (allowing overlapping) Eliminate band guards between carriers – Selective Fading – Very short pulses – ISI is compartively long – EQs are then very long – Poor spectral efficiency because of band guards Drawbacks – It is easy to exploit Frequency diversity – Flat Fading per carrier – N long pulses – ISI is comparatively short – N short EQs needed – Poor spectral efficiency because of band guards Advantages Furthermore – It allows to deploy 2D coding techniques – Dynamic signalling N carriers B Pulse length ~ N/B Similar to FDM technique – Data are shared amongseveral carriers and simultaneously transmitted B Pulse length ~1/B – Data are transmited over only one carrier Channel Guard bands Channelization
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Orthogonal Frequency Division Modulation. Data coded in frequency domain N carriers B Transformation to time domain: each frequency is a sine wave in time, all added up. f Transmit Symbol: 8 periods of f 0 Symbol: 4 periods of f 0 Symbol: 2 periods of f 0 + Receive time B Decode each frequency bin separately Channel frequency response f f Time-domain signal Frequency-domain signal
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OFDM uses multiple carriers to modulate the data. N carriers B Modulation technique A user utilizes all carriers to transmit its data as coded quantity at each frequency carrier, which can be quadrature-amplitude modulated (QAM). Intercarrier Separation = 1/(symbol duration) – No intercarrier guard bands – Controlled overlapping of bands – Maximum spectral efficiency (Nyquist rate) – Very sensitive to freq. synchronization – Easy implementation using IFFTs Features Data Carrier T=1/f 0 Time f 0 B Frequency One OFDM symbol Time-frequency grid
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OFDM Modulation and Demodulation using FFTs b0 b1 b2. bN-1 Data coded in frequency domain: one symbol at a time IFFT Inverse fast Fourier transform Data in time domain: one symbol at a time d0 d1 d2 d3. dN-1 time f P/S Parallel to serial converter Transmit time-domain samples of one symbol d0, d1, d2, …., dN-1 Receive time-domain samples of one symbol d0’, d1’, …., dN-1’ S/P Serial to parallel converter d0’ d1’ d2’. dN-1’ time FFT Fast Fourier transform b0’ b1’ b2’. bN-1’ f Decode each frequency bin independently
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Loss of orthogonality (by frequency offset) Transmission pulses Reception pulse with offset I m 2 ( ) m T 2 1 m 2 m 1 N 1 T 2 23 14 for N 1 (N 5 Is enough ) Interference between channels k and k+m Summing up m Asymetric
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Loss of orthogonality (time) Let us assume a misadjustment 2 consecutive symbols 00.010.020.030.040.050.060.070.08 10 15 20 25 30 35 40 45 Typical deviation for the relative misadjustment ICI in dB N=8 N=64 ICI due to loss of orthogonaliy assumed an Uniform r.v. Max. practical limit Doubling N means 3 dB more ICI Per carrier In average, the interfering power in any carrier is Or approximately, when <<T independent on m 00.10.20.30.40.50.60.70.80.91 -50 -45 -40 -35 -30 -25 -20 -15 -10 -5 0 Relative misadjustment Interference en dB Loss for 16 carriers m=1 m=5 m=10 Then Zone of interest if m=k-l
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Including a “cyclic prefix” CP Passing the channel h(n) i (t) j (t) h(n)=(1) –n /n n=0,…,23 j (t) i (t) i (t) To combat the time dispersion: including ‘special’ time guards in the symbol transitions CP T Tc copy Furthemore it converts Linear conv. = Cyclic conv. (Method: overlap-save) CP functions: – It acomodates the decaying transient of the previous symbol – It avoids the initial transient reachs the current symbol Including the Cyclic Prefix Symbol: 8 periods of f i Symbol: 4 periods of f i Initial transient remains within the CP Final transient remains within the CP The inclusion of a CP maintains the orthogonality Passing the channel h(n) Initial transient Decaying transient Channel: Symbol: 8 periods of f i Symbol: 4 periods of f i Without the Cyclic Prefix Loss of orthogonality
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802.11a System Specification l Sampling (chip) rate: 20MHz l Chip duration: 50ns l Number of FFT points: 64 FFT symbol period: 3.2 s Cyclic prefix period: 16 chips or 0.8 s »Typical maximum indoor delay spread < 400ns »OFDM frame length: 80 chips or 4 s »FFT symbol length / OFDM frame length = 4/5 l Modulation scheme »QPSK: 2bits/sample »16QAM: 4bits/sample »64QAM: 6bits/sample l Coding: rate ½ convolutional code with constraint length 7 GI2T1GIOFDM SymbolGIOFDM SymbolT2 t1t2t3 t4t5t6 t7t8 t9t10 Short training sequence: AGC and frequency offset Long training sequence: Channel estimation
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Frequency diversity using coding Random errors: primarily introduced by thermal and circuit noise. Channel-selected errors: introduced by magnitude distortion in channel frequency response. Data bits Bad carriers T=1/f 0 Time f 0 B Frequency Time-frequency grid Frequency response Errors are no longer random. Interleaving is often used to scramble the data bits so that standard error correcting codes can be applied. f
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Spectrum Mask Frequency (MHz) f carrier Power Spectral Density 9112030 -9-11 -20-30 -20 dB -28 dB -40 dB Requires extremely linear power amplifier design.
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Adjacent Channel and Alternate Channel Rejection Requires joint design of the anti-aliasing filter and ADC. 16 dB blocker 32 dB blocker Signal Frequency
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OFDM Receiver Design Yun Chiu, Dejan Marković, Haiyun Tang, Ning Zhang EE225C Final Project Report, 12 December 2000
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Introduction to OFDM l Basic idea »Using a large number of parallel narrow-band sub- carriers instead of a single wide-band carrier to transport information l Advantages »Very easy and efficient in dealing with multi-path »Robust again narrow-band interference l Disadvantages »Sensitive to frequency offset and phase noise »Peak-to-average problem reduces the power efficiency of RF amplifier at the transmitter l Adopted for various standards –DSL, 802.11a, DAB, DVB
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l Data set to be encoded on sub-carriers l IFFT at transmitter l FFT at receiver OFDM Signal Representation
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Cyclic Prefix TgTg T max TxTx Multi-path components T Sampling start
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OFDM System Block Diagram
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Synchronization l Frame detection l Frequency offset compensation l Sampling error »Usually less 100ppm and can be ignored –100ppm = off 1% of a sample every 100 samples TgTg T Frame start
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Channel Estimation
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System Pilot Structure
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Synchronization, Frequency Offset Compensation
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Outline IEEE 802.11a OFDM Transmitter Model Receiver Synchronization Module A Robust Double Correlation (Correlation & Auto- Correlation) Based Algorithm Receiver Frequency Offset Estimation Module A Coarse-Fine Joint Estimation Algorithm with Decision- Alignment Error Correction Receiver Frequency Offset Compensation Module Performance Summary
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IEEE 802.11a OFDM Txer Short Preamble Gen. Long Preamble Gen. OFDM Data Path
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Short & Long Preambles Short Preamble Long Preamble Period = 16 Chips Period = 64 Chips
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Correlation of Short Preamble Correlation Coarse Timing Fine Timing Auto- Correlation
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Synchronization Moving Auto- Corr. Unit Moving SP Corr. Unit
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Impairments: Multi-Path Channel Ch. Impulse Response Auto-Correlation w/ Multi-Path Channel Response.
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Impairments: Frequency Offset
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Fine Frequency Offset Est. Complex Multiplier Sync. Signal Accumulator
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Coarse-Fine Joint Estimation & Decision Alignment Error Correction Folding ADC Coarse Fine ±100ppm f c @ 5.8GHz Average over 16 chips Average over 64 chips
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Frequency Offset Compensation Joint Coarse- Fine Est. Offset Corr. Decision Alignment Channel
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Performance Summary ParametersMetrics Number of sub-carriers48 data +4 pilot OFDM symbol freq. 4 s Modulation SchemeBPSK up to 64-QAM Sampling clock freq.20 MHz Sync. Frame Start Accuracy 8 chips (CP = 16 chips) Freq. Offset Est. Range ± 5 = ± 100ppm @ 5.8 GHz Freq. Offset Est. Accuracy1% (@ 15dB SNR) Critical path delay12.7 ns Silicon area 397,080 m 2 Total power consumption3.4 mW @ 20 MHz
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