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OFDM Basics.ppt

1. The document discusses multi-carrier transmission over mobile radio channels. It introduces OFDM and describes how multipath reception affects different modulation techniques. 2. It then discusses receivers for OFDM and MC-CDMA, including synchronous MC-CDMA receivers that use FFT processing followed by weighting and code despreading. 3. The effects of Doppler spread on OFDM and MC-CDMA are analyzed, including intercarrier interference and its impact on BER performance in mobile channels. The channel is modeled using a Taylor expansion of the time-varying amplitude.

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Multi-Carrier Transmission over Mobile Radio Channels Jean-Paul M.G. Linnartz Nat.Lab., Philips Research
Outline • Introduction to OFDM • Introduction to multipath reception • Discussion of receivers for OFDM and MC-CDMA • Introduction to Doppler channels • Intercarrier Interference, FFT Leakage • New receiver designs • Simulation of Performance • Conclusions
OFDM OFDM: a form of MultiCarrier Modulation. • Different symbols are transmitted over different subcarriers • Spectra overlap, but signals are orthogonal. • Example: Rectangular waveform -> Sinc spectrum
I-FFT: OFDM Transmission Transmission of QAM symbols on parallel subcarriers Overlapping, yet orthogonal subcarriers cos(wct+ wst) cos(wct) cos(wct+ iwst) cos(wct+ (N-1)wst) User symbols Serial-to- parallel = Serial-to- Parallel I-FFT Parallel-to- Serial
OFDM Subcarrier Spectra OFDM signal strength versus frequency. Rectangle <- FFT -> Sinc before channel after channel Frequency
Applications Fixed / Wireline: • ADSL Asymmetric Digital Subscriber Line Mobile / Radio: • Digital Audio Broadcasting (DAB) • Digital Video Broadcasting - Terrestrial (DVB-T) • Hiperlan II • Wireless 1394 • 4G (?)
The Wireless Multipath Channel
The Mobile Multipath Channel Delay spread Doppler spread Frequency Time FT Frequency FT Frequency Time
Effects of Multipath Delay and Doppler Frequency Time Narrowband Frequency Time OFDM Wideband QAM Frequency Time
Effects of Multipath (II) Frequency Time + - + - - + - + DS-CDMA Frequency Time + - - Frequency Hopping Frequency Time + - + - + - + - + - + - MC-CDMA
Multi-Carrier CDMA Various different proposals. • (1) DS-CDMA followed by OFDM • (2) OFDM followed by DS-CDMA • (3) DS-CDMA on multiple parallel carriers First research papers on system (1) in 1993: – Fettweis, Linnartz, Yee (U.C. Berkeley) – Fazel (Germany) – Chouly (Philips LEP) System (2): Vandendorpe (LLN) System (3): Milstein (UCSD); Sourour and Nakagawa
Multi-Carrier CDM Transmitter What is MC-CDMA (System 1)? • a form of Direct Sequence CDMA, but after spreading a Fourier Transform (FFT) is performed. • a form of Orthogonal Frequency Division Multiplexing (OFDM), but with an orthogonal matrix operation on the bits. • a form of Direct Sequence CDMA, but the code sequence is the Fourier Transform of the code. • a form of frequency diversity. Each bit is transmitted simultaneously (in parallel) on many different subcarriers. P/S I-FFT N S/P N B Code Matrix C N A
MC-CDM (Code Division Multiplexing) in Downlink In the ‘forward’ or downlink (base-to-mobile): all signals originate at the base station and travel over the same path. One can easily exploit orthogonality of user signals. It is fairly simple to reduce mutual interference from users within the same cell, by assigning orthogonal Walsh-Hadamard codes. BS MS 2 MS 1
Synchronous MC-CDM receiver The MC-CDM receiver • separates the various subcarrier signals (FFT) • weights these subcarriers in W, and • does a code despreading in C-1: (linear matrix over the complex numbers) Compare to C-OFDM: W := equalization or AGC per subcarrier C-1 := Error correction decoder (non-linear operation) S/P P/S I-Code Matrix C-1 FFT N N N Y Weigh Matrix W N A
Synchronous MC-CDM receiver Receiver strategies (How to pick W ?) • equalization (MUI reduction) w = 1/b • maximum ratio combining (noise reduction) w = b • Wiener Filtering (joint optimization) w = b/(b2 + c) Next step: W can be reduced to an automatic gain control, per subcarrier, if no ICI occurs S/P P/S I-Code Matrix C-1 FFT N N N Y Weigh Matrix W N A
Synchronous MC-CDM receiver • Optimum estimate per symbol B is obtained from B = EB|Y = C-1EA|Y = C-1A. • Thus: optimum linear receiver can implement FFT - W - C-1 • Orthogonality Principle: E(A-A)YH = 0N, where A = WYH • Wiener Filtering: W = E AYH (EYYH)-1 • EAYH diagonal matrix of signal power • EYYH diagonal matrix of signal plus noise power • W can be reduced to an AGC, per subcarrier S/P P/S I-Code Matrix C-1 FFT N N N Y Weigh Matrix W N A B s * * T N β β β w 0 + 
MC-CDM BER analysis Rayleigh fading channel – Exponential delay spread – Doppler spread with uniform angle of arrival Perfect synchronisation Perfect channel estimation, no estimation of ICI Orthogonal codes Pseudo MMSE (no cancellation of ICI)
Composite received signal Wanted signal Multi-user Interference (MUI) Intercarrier interference (ICI)          +          0 0 0 , 1 0 , , 1 0 , 0 0 ] [ ] [ m n n N n n m n n N n n n s m n c n c w w N T b x b b              ] [ ] [ 0 , 1 0 , 1 1 n c n c w b T x k n n N n n n N k k s MUI b      +  +  +    +  0 0 n , n , n 1 0 n ] [n c w a T x n N n s ICI b
Composite received signal Wanted signal Multi-User Interference (MUI) Intercarrier interference (ICI)                         1 0 2 , ch 1 0 2 , ch 0 2 0 1 1 2 2 E E ) ( ) ( E E 1 N n n n N n n m k N k k ICI w m n c n c b N b  2 , , , , ch 1 1 2 2 2 * ch 2 E E E E                 +    n n A n n n n n A n n n N k k s MUI MUI MUI w w b N T x x b b  n n N n n n s w β N T b x , 1 0 , 0 0    
BER for MC-CDMA BER for BPSK versus Eb/N0 (1) 8 subcarriers (2) 64 subcarriers (3) infinitely many subcarriers (4) 8 subc., short delay spread (5) 8 subc., typical delay spread 10-5 10-4 10-3 10-2 10-1 5 10 15 Local-mean En/N0 Eb/N0Eb/No (dB) (1) (2) (3) (4) (5) Avg. BER AWGN OFDM Local-mean Eb/N0
Capacity relative to non-fading channel Coded-OFDM same as N fading channels For large P0Ts/N0 on a Rayleigh fading channel, OFDM has 0.4 bit less capacity per dimension than a non-fading channel. MC-CDM Data Processing Theorem: COFDM = CMC-CDM In practise, we loose a little. In fact, for infinitely many subcarriers, CMC-CDM = ½ log2(1 + P0Ts/N0). where  is MC-CDM figure of merit, typically -4 .. -6 dB.  )   +           0 2 2 1 0 0 0 0 2 1 log exp 2 dx x x T P N T P N C s s OFDM                  s s OFDM T P N E T P N C 0 0 1 0 0 2 2 exp 2 ln 1
Capacity Capacity per dimension versus local-mean EN/N0, no Doppler. -5 0 5 10 15 20 25 30 35 40 0 1 2 3 4 5 6 7 Local-meanEn/N0(dB) Capacity: Bits per Subcarrier -* : Rayleigh * : MC-CDMA - : LTI Non-fading, LTI Rayleigh MC-CDM
OFDM and MC-CDMA in a rapidly time-varying channel Doppler spread is the Fourier-dual of a delay spread
Doppler Multipath Channel Describe the received signal with all its delayed and Doppler-shifted components Compact this model into a convenient form, based on time-varying amplitudes. Make a (discrete-frequency) vector channel representation Exploit this to design better receivers
Mobile Multipath Channel Collection of reflected waves, each with • random angle of arrival • random delay Angle of arrival is uniform Doppler shift is cos(angle) U-shaped power density spectrum Doppler Spectrum
ICI caused by Doppler 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 10 -4 10 -3 10 -2 10 -1 10 0 Norm alizedDoppler [fm /fsub] Power, Variance of ICI P0 P1 P2 P3 Power or variance of ICI Doppler spread / Subcarrier Spacing Neighboring subcarrier 2nd tier subcarrier 3rd tier subcarrier
BER in a mobile channel 0 5 10 15 20 25 30 35 40 10 -7 10 -6 10 -5 10 -4 10 -3 10 -2 10 -1 10 0 AntennaSpeed(m /s) Local-Mean BER for BPSK OFDM,10dB MC-CDMA,20dB 30dB MC-CDMA,10dB OFDM,20dB OFDM,30dB • Local-mean BER for BPSK, versus antenna speed. • Local mean SNR of 10, 20 and 30 dB. • Comparison between MC-CDMA and uncoded OFDM for fc = 4 GHz • Frame durationTs= 896ms • FFT size: N = 8192. •Sub. spacing fs = 1.17 kHz •Data rate 9.14 Msymbol/s. Antenna Speed [m/s]
Doppler Multipath Channel Received signal r(t) Channel model: Iw reflected waves have the following properties: • Di is the amplitude • wI is the Doppler shift • Ti is the delay OFDM parameters: •N is the number of subcarriers •Ts is the frame duration •an is the code-multiplexed data •wc is the carrier frequency •ws is the subcarrier spacing ) ( } ) )( ( exp{ ) ( 1 0 1 0 t n t j T t n j D a t r w I i i i s c i n N n + +  +        w w w
Taylor Expansion of Amplitude Rewrite the Channel Model as follows Tayler expansion of the amplitude Vn(t) = vn (0)+ vn (1) (t-t) + vn (2) (t-t)2/2 + .. . vn (q) : the q-th derivative of amplitude wrt time, at instant t = t. vn (p) is a complex Gaussian random variable. ) ( } ) ( exp{ ) ( ) ( 1 0 t n t n j t V a t r s c N n n n + +     w w  )     + +   1 0 ) ( } ) ( exp{ w I i t i i s c i q i q n j T n j D j v w w w w ) ( } ) )( ( exp{ ) ( 1 0 1 0 t n t j T t n j D a t r w I i i i s c i n N n + +  +        w w w
Random Complex-Gaussian Amplitude It can be shown that for p + q is even and 0 for p + q is odd. • This defines the covariance matrix of subcarrier amplitudes and derivatives, • allows system modeling and simulation between the input of the transmit I-FFT and output of the receive FFT.  ) s rms q p q q p D q m p n T m n j j q p q p f v v w  ) ( 1 ) 1 ( ! )! ( ! )! 1 ( 2 E ) *( ) (  +  +  +  + +
DF Vector Channel Model Received signal Y = [y0, y1, … yN-1 ], Let’s ignore f : frequency offset t : timing offset We will denote  =  (0) and  =  (1) • For integer ,  :: 0 (orthogonal subcarriers) •  models ICI following from derivatives of amplitudes • 0 does not carry ICI but the wanted signal  )   m N n q q q m n q n f t s n m n q T v n j a y f +              1 0 0 ) ( ) ( ! exp  w Complex amplitudes and derivatives System constants (eg sinc) determined by waveform
DF-Domain Simulation Simulation of complex-fading amplitudes of a Rayleigh channel with Doppler and delay spread • Pre-compute an N-by-N matrix U, such that UUH is the channel covariance matrix  with elements n,m = Evn (0)vm*(0) – Simply use an I-FFT, multiply by exponential delay profile and FFT • Generate two i.i.d vectors of complex Gaussian random variables, G and G’, with unity variance and length N. • Calculate V = U G. • Calculate V(1) = 2fT U G’.
DF Vector Channel Model Received signal Y = [y0, y1, … yN-1 ], •  models ICI following from derivatives of amplitudes • 0 does not carry ICI but the wanted signal   N T A V A V I χ Y N +         * '. * . 3 0               +  +     0 2 1 2 0 1 1 1 0 3 .. .. .. .. .. .. ..          N N N N FFT leakage Amplitudes & Derivatives User data
Possible Receiver Approaches Receiver 1) Try to invert adaptive matrix (Alexei Gorokhov) 2) See it as Multi-user detection: (J.P. Linnartz, Ton Kalker) – try to separate V .* A and V(1).* A 3) Decision Feedback (Jan Bergmans) – estimate iteratively V, V (1) and A ) DIAG( ) DIAG( ) 1 ( 0 V V χ  +   N AT V A V I χ Y N +         * . ' * . 0
Receiver 1: Matrix Inversion • Estimate amplitudes V and complex derivatives V (1) • create the matrix Q1 = DIAG(V)+ T  DIAG(V(1)) • Invert Q1 to get Q1 -1 (channel dependent) • Compute Q1 -1Y Zero-forcing:  For perfect estimates V and V (1), Q1 -1Y = A + Q1 -1N,  i.e., you get enhanced noise. MMSE Wiener filtering inversion W Channel Estimator Slicer Q -1 Y 3 X1 X2 X3 + x x V V’ A N V’ A V
Receiver 1: MMSE Matrix Inversion Receiver sees Y = Q A + N, with Q=DIAG(V)+ T DIAG(V(1))  Calculate matrix Q = DIAG(V)+ T DIAG(V(1))  Compute MMSE filter W = QH [Q QH + n 2 IN]-1. Performance evaluation: • Signal power per subcarrier • Residual ICI and Noise enhancement from W
Receiver 1: Matrix Inversion Simulation of channel for N = 64, v = 200 km/h fc = 17 GHz, TRMS = 1 ms, sampling at T = 1ms. fDoppler = 3.14 kHz, Subcarrier spacing fsr = 31.25 kHz, signal-to-ICI = 18 dB Amplitudes First derivatives Determined by speed of antenna, and carrier frequency
Receiver 1: Matrix Inversion SNR of decision variable. Simulation for N = 64, MMSE Wiener filtering to cancel ICI MMSE ICI canceller Conventional OFDM
Performance of (Simplified) Matrix Inversion N = 64, v = 200 km/h, fc = 17 GHz, TRMS = 1 ms, sampling at T = 1ms. fDoppler = 3.15 kHz, Subc. spacing fsr = 31.25 kHz: Compare to DVB-T: v = 140 km/h, fc = 800MHz: fdoppler = 100 Hz while fsr = 1.17 kHz 5 10 15 20 25 30 0 5 10 15 20 25 30 Input SNR Conventional OFDM MMSE equalization simplified MMSE k = 4 Conv OFDM MMSE Output SINR
Receiver 1: Subconclusion • Performance improvement of 4 .. 7 • Complexity can be reduced to ~2kN, k ~ 5 .. 10. • Estimation of V(1) to be developed, V is already being estimated
Receiver 3: Decision Feedback Estimate • data, • amplitudes and • derivatives iteratively
Receiver 3: Decision Feedback Iteratively do the following: • Compare the signal before and after the slicer • Difference = noise + ICI + decision errors • Invert  to retrieve modulated derivatives from ICI – V(1).*A = -1 ICI – MMSE to minimize noise enhancements • Remove modulation 1/A • Smooth to exploit correlation in V(1) • Modulate with A • Feed through  to estimate ICI • Subtract estimated ICI
Receiver 3: DFE Estimate V(1) in side chain Pilot Slicer M6 + x x + Cancel Doppler Estimated Amplitudes 3 ICI - + M7 Z10 Z8 Z7 Z6 Y2 Y0 3 X1 X2 X3 + x x V V’ A N Z9 =V’ A 1/A A.*V V - A INT Channel Model
Performance of Receiver 3: DFE Variance of decision variable after iterative ICI cancellation versus variance in conventional receiver 10 -2 10 -1 10 0 10 1 10 2 10 -3 10 -2 10 -1 10 0 10 1 10 2 V ariance C onventional V ariance New S ystem 3 Variance decision variable in conventional receiver Variance of decision variable in DFE receiver after ICI cancelling
Error Count Receiver 3: DFE N = 64 out of 8192 subcarriers, v = 30 m/s, fc = 600 MHz TRMS / NT= 0.03, fDoppler = 60 Hz, Subcarrier spacing fsr = 1.17 kHz 0 10 20 30 40 50 60 70 -30 -25 -20 -15 -10 -5 0 5 10 Decision Feedback Sample run N=64 9 errors -> 4 errors Subcarrier Number Amplitude Amplitudes Derivatives
Conclusions Modeling the Doppler channel as a set of time-varying subcarrier amplitudes leads to useful receiver designs. Estimation of V(1) is to be added, V is already being estimated Basic principle demonstrated by simulation Gain about – 3 .. 6dB, – factor of 2 or more in uncoded BER, – factor 2 or more in velocity. Promising methods to cancel FFT leakage (DVB-T, 4G) More at http://wireless.per.nl
Further Research Work Optimise the receiver design and estimation of derivatives Can we play with the waveform (or window) to make the tails of the filter  steeper? Can we interpret the derivatives as a diversity channel? Can estimation of derivatives be combined with synchronisation? Isn’t this even more promising with MC-CDMA? Apply it to system design.

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OFDM Basics.ppt

  • 1.
    Multi-Carrier Transmission over MobileRadio Channels Jean-Paul M.G. Linnartz Nat.Lab., Philips Research
  • 2.
    Outline • Introduction toOFDM • Introduction to multipath reception • Discussion of receivers for OFDM and MC-CDMA • Introduction to Doppler channels • Intercarrier Interference, FFT Leakage • New receiver designs • Simulation of Performance • Conclusions
  • 3.
    OFDM OFDM: a formof MultiCarrier Modulation. • Different symbols are transmitted over different subcarriers • Spectra overlap, but signals are orthogonal. • Example: Rectangular waveform -> Sinc spectrum
  • 4.
    I-FFT: OFDM Transmission Transmissionof QAM symbols on parallel subcarriers Overlapping, yet orthogonal subcarriers cos(wct+ wst) cos(wct) cos(wct+ iwst) cos(wct+ (N-1)wst) User symbols Serial-to- parallel = Serial-to- Parallel I-FFT Parallel-to- Serial
  • 5.
    OFDM Subcarrier Spectra OFDMsignal strength versus frequency. Rectangle <- FFT -> Sinc before channel after channel Frequency
  • 6.
    Applications Fixed / Wireline: •ADSL Asymmetric Digital Subscriber Line Mobile / Radio: • Digital Audio Broadcasting (DAB) • Digital Video Broadcasting - Terrestrial (DVB-T) • Hiperlan II • Wireless 1394 • 4G (?)
  • 7.
  • 9.
    The Mobile MultipathChannel Delay spread Doppler spread Frequency Time FT Frequency FT Frequency Time
  • 10.
    Effects of MultipathDelay and Doppler Frequency Time Narrowband Frequency Time OFDM Wideband QAM Frequency Time
  • 11.
    Effects of Multipath(II) Frequency Time + - + - - + - + DS-CDMA Frequency Time + - - Frequency Hopping Frequency Time + - + - + - + - + - + - MC-CDMA
  • 12.
    Multi-Carrier CDMA Various differentproposals. • (1) DS-CDMA followed by OFDM • (2) OFDM followed by DS-CDMA • (3) DS-CDMA on multiple parallel carriers First research papers on system (1) in 1993: – Fettweis, Linnartz, Yee (U.C. Berkeley) – Fazel (Germany) – Chouly (Philips LEP) System (2): Vandendorpe (LLN) System (3): Milstein (UCSD); Sourour and Nakagawa
  • 13.
    Multi-Carrier CDM Transmitter Whatis MC-CDMA (System 1)? • a form of Direct Sequence CDMA, but after spreading a Fourier Transform (FFT) is performed. • a form of Orthogonal Frequency Division Multiplexing (OFDM), but with an orthogonal matrix operation on the bits. • a form of Direct Sequence CDMA, but the code sequence is the Fourier Transform of the code. • a form of frequency diversity. Each bit is transmitted simultaneously (in parallel) on many different subcarriers. P/S I-FFT N S/P N B Code Matrix C N A
  • 14.
    MC-CDM (Code DivisionMultiplexing) in Downlink In the ‘forward’ or downlink (base-to-mobile): all signals originate at the base station and travel over the same path. One can easily exploit orthogonality of user signals. It is fairly simple to reduce mutual interference from users within the same cell, by assigning orthogonal Walsh-Hadamard codes. BS MS 2 MS 1
  • 15.
    Synchronous MC-CDM receiver TheMC-CDM receiver • separates the various subcarrier signals (FFT) • weights these subcarriers in W, and • does a code despreading in C-1: (linear matrix over the complex numbers) Compare to C-OFDM: W := equalization or AGC per subcarrier C-1 := Error correction decoder (non-linear operation) S/P P/S I-Code Matrix C-1 FFT N N N Y Weigh Matrix W N A
  • 16.
    Synchronous MC-CDM receiver Receiverstrategies (How to pick W ?) • equalization (MUI reduction) w = 1/b • maximum ratio combining (noise reduction) w = b • Wiener Filtering (joint optimization) w = b/(b2 + c) Next step: W can be reduced to an automatic gain control, per subcarrier, if no ICI occurs S/P P/S I-Code Matrix C-1 FFT N N N Y Weigh Matrix W N A
  • 17.
    Synchronous MC-CDM receiver •Optimum estimate per symbol B is obtained from B = EB|Y = C-1EA|Y = C-1A. • Thus: optimum linear receiver can implement FFT - W - C-1 • Orthogonality Principle: E(A-A)YH = 0N, where A = WYH • Wiener Filtering: W = E AYH (EYYH)-1 • EAYH diagonal matrix of signal power • EYYH diagonal matrix of signal plus noise power • W can be reduced to an AGC, per subcarrier S/P P/S I-Code Matrix C-1 FFT N N N Y Weigh Matrix W N A B s * * T N β β β w 0 + 
  • 18.
    MC-CDM BER analysis Rayleighfading channel – Exponential delay spread – Doppler spread with uniform angle of arrival Perfect synchronisation Perfect channel estimation, no estimation of ICI Orthogonal codes Pseudo MMSE (no cancellation of ICI)
  • 19.
    Composite received signal Wantedsignal Multi-user Interference (MUI) Intercarrier interference (ICI)          +          0 0 0 , 1 0 , , 1 0 , 0 0 ] [ ] [ m n n N n n m n n N n n n s m n c n c w w N T b x b b              ] [ ] [ 0 , 1 0 , 1 1 n c n c w b T x k n n N n n n N k k s MUI b      +  +  +    +  0 0 n , n , n 1 0 n ] [n c w a T x n N n s ICI b
  • 20.
    Composite received signal Wantedsignal Multi-User Interference (MUI) Intercarrier interference (ICI)                         1 0 2 , ch 1 0 2 , ch 0 2 0 1 1 2 2 E E ) ( ) ( E E 1 N n n n N n n m k N k k ICI w m n c n c b N b  2 , , , , ch 1 1 2 2 2 * ch 2 E E E E                 +    n n A n n n n n A n n n N k k s MUI MUI MUI w w b N T x x b b  n n N n n n s w β N T b x , 1 0 , 0 0    
  • 21.
    BER for MC-CDMA BERfor BPSK versus Eb/N0 (1) 8 subcarriers (2) 64 subcarriers (3) infinitely many subcarriers (4) 8 subc., short delay spread (5) 8 subc., typical delay spread 10-5 10-4 10-3 10-2 10-1 5 10 15 Local-mean En/N0 Eb/N0Eb/No (dB) (1) (2) (3) (4) (5) Avg. BER AWGN OFDM Local-mean Eb/N0
  • 22.
    Capacity relative to non-fadingchannel Coded-OFDM same as N fading channels For large P0Ts/N0 on a Rayleigh fading channel, OFDM has 0.4 bit less capacity per dimension than a non-fading channel. MC-CDM Data Processing Theorem: COFDM = CMC-CDM In practise, we loose a little. In fact, for infinitely many subcarriers, CMC-CDM = ½ log2(1 + P0Ts/N0). where  is MC-CDM figure of merit, typically -4 .. -6 dB.  )   +           0 2 2 1 0 0 0 0 2 1 log exp 2 dx x x T P N T P N C s s OFDM                  s s OFDM T P N E T P N C 0 0 1 0 0 2 2 exp 2 ln 1
  • 23.
    Capacity Capacity per dimensionversus local-mean EN/N0, no Doppler. -5 0 5 10 15 20 25 30 35 40 0 1 2 3 4 5 6 7 Local-meanEn/N0(dB) Capacity: Bits per Subcarrier -* : Rayleigh * : MC-CDMA - : LTI Non-fading, LTI Rayleigh MC-CDM
  • 24.
    OFDM and MC-CDMAin a rapidly time-varying channel Doppler spread is the Fourier-dual of a delay spread
  • 25.
    Doppler Multipath Channel Describethe received signal with all its delayed and Doppler-shifted components Compact this model into a convenient form, based on time-varying amplitudes. Make a (discrete-frequency) vector channel representation Exploit this to design better receivers
  • 26.
    Mobile Multipath Channel Collectionof reflected waves, each with • random angle of arrival • random delay Angle of arrival is uniform Doppler shift is cos(angle) U-shaped power density spectrum Doppler Spectrum
  • 27.
    ICI caused byDoppler 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 10 -4 10 -3 10 -2 10 -1 10 0 Norm alizedDoppler [fm /fsub] Power, Variance of ICI P0 P1 P2 P3 Power or variance of ICI Doppler spread / Subcarrier Spacing Neighboring subcarrier 2nd tier subcarrier 3rd tier subcarrier
  • 28.
    BER in amobile channel 0 5 10 15 20 25 30 35 40 10 -7 10 -6 10 -5 10 -4 10 -3 10 -2 10 -1 10 0 AntennaSpeed(m /s) Local-Mean BER for BPSK OFDM,10dB MC-CDMA,20dB 30dB MC-CDMA,10dB OFDM,20dB OFDM,30dB • Local-mean BER for BPSK, versus antenna speed. • Local mean SNR of 10, 20 and 30 dB. • Comparison between MC-CDMA and uncoded OFDM for fc = 4 GHz • Frame durationTs= 896ms • FFT size: N = 8192. •Sub. spacing fs = 1.17 kHz •Data rate 9.14 Msymbol/s. Antenna Speed [m/s]
  • 29.
    Doppler Multipath Channel Receivedsignal r(t) Channel model: Iw reflected waves have the following properties: • Di is the amplitude • wI is the Doppler shift • Ti is the delay OFDM parameters: •N is the number of subcarriers •Ts is the frame duration •an is the code-multiplexed data •wc is the carrier frequency •ws is the subcarrier spacing ) ( } ) )( ( exp{ ) ( 1 0 1 0 t n t j T t n j D a t r w I i i i s c i n N n + +  +        w w w
  • 30.
    Taylor Expansion ofAmplitude Rewrite the Channel Model as follows Tayler expansion of the amplitude Vn(t) = vn (0)+ vn (1) (t-t) + vn (2) (t-t)2/2 + .. . vn (q) : the q-th derivative of amplitude wrt time, at instant t = t. vn (p) is a complex Gaussian random variable. ) ( } ) ( exp{ ) ( ) ( 1 0 t n t n j t V a t r s c N n n n + +     w w  )     + +   1 0 ) ( } ) ( exp{ w I i t i i s c i q i q n j T n j D j v w w w w ) ( } ) )( ( exp{ ) ( 1 0 1 0 t n t j T t n j D a t r w I i i i s c i n N n + +  +        w w w
  • 31.
    Random Complex-Gaussian Amplitude Itcan be shown that for p + q is even and 0 for p + q is odd. • This defines the covariance matrix of subcarrier amplitudes and derivatives, • allows system modeling and simulation between the input of the transmit I-FFT and output of the receive FFT.  ) s rms q p q q p D q m p n T m n j j q p q p f v v w  ) ( 1 ) 1 ( ! )! ( ! )! 1 ( 2 E ) *( ) (  +  +  +  + +
  • 32.
    DF Vector ChannelModel Received signal Y = [y0, y1, … yN-1 ], Let’s ignore f : frequency offset t : timing offset We will denote  =  (0) and  =  (1) • For integer ,  :: 0 (orthogonal subcarriers) •  models ICI following from derivatives of amplitudes • 0 does not carry ICI but the wanted signal  )   m N n q q q m n q n f t s n m n q T v n j a y f +              1 0 0 ) ( ) ( ! exp  w Complex amplitudes and derivatives System constants (eg sinc) determined by waveform
  • 33.
    DF-Domain Simulation Simulation ofcomplex-fading amplitudes of a Rayleigh channel with Doppler and delay spread • Pre-compute an N-by-N matrix U, such that UUH is the channel covariance matrix  with elements n,m = Evn (0)vm*(0) – Simply use an I-FFT, multiply by exponential delay profile and FFT • Generate two i.i.d vectors of complex Gaussian random variables, G and G’, with unity variance and length N. • Calculate V = U G. • Calculate V(1) = 2fT U G’.
  • 34.
    DF Vector ChannelModel Received signal Y = [y0, y1, … yN-1 ], •  models ICI following from derivatives of amplitudes • 0 does not carry ICI but the wanted signal   N T A V A V I χ Y N +         * '. * . 3 0               +  +     0 2 1 2 0 1 1 1 0 3 .. .. .. .. .. .. ..          N N N N FFT leakage Amplitudes & Derivatives User data
  • 35.
    Possible Receiver Approaches Receiver 1)Try to invert adaptive matrix (Alexei Gorokhov) 2) See it as Multi-user detection: (J.P. Linnartz, Ton Kalker) – try to separate V .* A and V(1).* A 3) Decision Feedback (Jan Bergmans) – estimate iteratively V, V (1) and A ) DIAG( ) DIAG( ) 1 ( 0 V V χ  +   N AT V A V I χ Y N +         * . ' * . 0
  • 36.
    Receiver 1: MatrixInversion • Estimate amplitudes V and complex derivatives V (1) • create the matrix Q1 = DIAG(V)+ T  DIAG(V(1)) • Invert Q1 to get Q1 -1 (channel dependent) • Compute Q1 -1Y Zero-forcing:  For perfect estimates V and V (1), Q1 -1Y = A + Q1 -1N,  i.e., you get enhanced noise. MMSE Wiener filtering inversion W Channel Estimator Slicer Q -1 Y 3 X1 X2 X3 + x x V V’ A N V’ A V
  • 37.
    Receiver 1: MMSEMatrix Inversion Receiver sees Y = Q A + N, with Q=DIAG(V)+ T DIAG(V(1))  Calculate matrix Q = DIAG(V)+ T DIAG(V(1))  Compute MMSE filter W = QH [Q QH + n 2 IN]-1. Performance evaluation: • Signal power per subcarrier • Residual ICI and Noise enhancement from W
  • 38.
    Receiver 1: MatrixInversion Simulation of channel for N = 64, v = 200 km/h fc = 17 GHz, TRMS = 1 ms, sampling at T = 1ms. fDoppler = 3.14 kHz, Subcarrier spacing fsr = 31.25 kHz, signal-to-ICI = 18 dB Amplitudes First derivatives Determined by speed of antenna, and carrier frequency
  • 39.
    Receiver 1: MatrixInversion SNR of decision variable. Simulation for N = 64, MMSE Wiener filtering to cancel ICI MMSE ICI canceller Conventional OFDM
  • 40.
    Performance of (Simplified)Matrix Inversion N = 64, v = 200 km/h, fc = 17 GHz, TRMS = 1 ms, sampling at T = 1ms. fDoppler = 3.15 kHz, Subc. spacing fsr = 31.25 kHz: Compare to DVB-T: v = 140 km/h, fc = 800MHz: fdoppler = 100 Hz while fsr = 1.17 kHz 5 10 15 20 25 30 0 5 10 15 20 25 30 Input SNR Conventional OFDM MMSE equalization simplified MMSE k = 4 Conv OFDM MMSE Output SINR
  • 41.
    Receiver 1: Subconclusion •Performance improvement of 4 .. 7 • Complexity can be reduced to ~2kN, k ~ 5 .. 10. • Estimation of V(1) to be developed, V is already being estimated
  • 42.
    Receiver 3: DecisionFeedback Estimate • data, • amplitudes and • derivatives iteratively
  • 43.
    Receiver 3: DecisionFeedback Iteratively do the following: • Compare the signal before and after the slicer • Difference = noise + ICI + decision errors • Invert  to retrieve modulated derivatives from ICI – V(1).*A = -1 ICI – MMSE to minimize noise enhancements • Remove modulation 1/A • Smooth to exploit correlation in V(1) • Modulate with A • Feed through  to estimate ICI • Subtract estimated ICI
  • 44.
    Receiver 3: DFE EstimateV(1) in side chain Pilot Slicer M6 + x x + Cancel Doppler Estimated Amplitudes 3 ICI - + M7 Z10 Z8 Z7 Z6 Y2 Y0 3 X1 X2 X3 + x x V V’ A N Z9 =V’ A 1/A A.*V V - A INT Channel Model
  • 45.
    Performance of Receiver3: DFE Variance of decision variable after iterative ICI cancellation versus variance in conventional receiver 10 -2 10 -1 10 0 10 1 10 2 10 -3 10 -2 10 -1 10 0 10 1 10 2 V ariance C onventional V ariance New S ystem 3 Variance decision variable in conventional receiver Variance of decision variable in DFE receiver after ICI cancelling
  • 46.
    Error Count Receiver 3:DFE N = 64 out of 8192 subcarriers, v = 30 m/s, fc = 600 MHz TRMS / NT= 0.03, fDoppler = 60 Hz, Subcarrier spacing fsr = 1.17 kHz 0 10 20 30 40 50 60 70 -30 -25 -20 -15 -10 -5 0 5 10 Decision Feedback Sample run N=64 9 errors -> 4 errors Subcarrier Number Amplitude Amplitudes Derivatives
  • 47.
    Conclusions Modeling the Dopplerchannel as a set of time-varying subcarrier amplitudes leads to useful receiver designs. Estimation of V(1) is to be added, V is already being estimated Basic principle demonstrated by simulation Gain about – 3 .. 6dB, – factor of 2 or more in uncoded BER, – factor 2 or more in velocity. Promising methods to cancel FFT leakage (DVB-T, 4G) More at http://wireless.per.nl
  • 48.
    Further Research Work Optimisethe receiver design and estimation of derivatives Can we play with the waveform (or window) to make the tails of the filter  steeper? Can we interpret the derivatives as a diversity channel? Can estimation of derivatives be combined with synchronisation? Isn’t this even more promising with MC-CDMA? Apply it to system design.