1 / 26

Channel Equalization Techniques

Channel Equalization Techniques. Fernando Gregorio Based on: 1-Adaptive Signal Processing, Benesty-Huang 2-Fundamentals of Adaptive Filtering, Ali H. Sayed. Outline. Introducction Channel equalization Linear equalizers Decision feedback equalizers

foster
Download Presentation

Channel Equalization Techniques

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Channel Equalization Techniques Fernando Gregorio Based on: 1-Adaptive Signal Processing, Benesty-Huang 2-Fundamentals of Adaptive Filtering, Ali H. Sayed

  2. Outline • Introducction • Channel equalization • Linear equalizers • Decision feedback equalizers • Adaptive algorithms for channel equalization • Adaptive linear equalizer • Adaptive DFE • Training and tracking • Simulations • Static channel • Time varying channel S88-4221 Seminar

  3. Introduction • In a communication system, the transmitter sends the information over an RF channel. • The channel distorts the transmitted signal befores it reaches the receiver. • The receiver ”task” is to figure out what signal was transmitted Turn the received signal in understandable information. S88-4221 Seminar

  4. Introduction • Intersymbol Interference (ISI) • Noise Noise Channel ISI desired signal noise S88-4221 Seminar

  5. Introduction The purpose of an equalizer is to reduce the ISI as much as possible to maximize the probability of correct decisions Noise Channel Equalizer S88-4221 Seminar

  6. Linear Equalizers • The current and the past values of the received signal are linearly weigthed by equalizer coefficients and summed to produce the output. • The ISI can be completely removed, without taking in consideration the resultanting noise enhacement  Zero forcing equalizer. • A substantial increment of the noise power is created using ZF equalizer. S88-4221 Seminar

  7. Linear Equalizers Mean-Square Error equalizer • From the point-of-view of minimizing error probability, it is adventageous to allow some residual ISI if this can reduce the noise power. • The MSE criterion attempts to minimize the total error between the slicer input and the transmitted data symbol. Transmit signal Power noise S88-4221 Seminar

  8. Decision-Feedback Equalizers • Simple nonlinear equalizer which is particulary useful for channel with severe amplitude distortion. • DFE uses desicion feedback to cancel the interferfence from symbols which have already have been detected. • The basic idea is that if the values of the symbols already detected are known (past decisions are assumed correct), then the ISI contributed by these symbols can be canceled exactly. S88-4221 Seminar

  9. Decision-Feedback Equalizers Decision feedback equalizer structure • The forward and feedback coefficients may be adjusted simultaneously to minimize the MSE. Feed back filter (FBF) Input Output Feed forward filter (FFF) + + Symbol decision Adjustment of filter coefficients S88-4221 Seminar

  10. Adaptive Equalization • The object is to adapt the coefficients to minimize the noise and intersymbol interference (depending on the type of equalizer) at the output. • The adaptation of the equalizer is driven by an error signal. The aim is to minimize: Error signal + Channel Equalizer S88-4221 Seminar

  11. Adaptive Equalization There are two modes that adaptive equalizers work; • Decision Directed Mode: The receiver decisions are used to generate the error signal. Decision directed equalizer adjustment is effective in tracking slow variations in the channel response. However, this approach is not effective during initial acqusition . • Training Mode: To make equalizer suitable in the initial acqusition duration, a training signal is needed. In this mode of operation, the transmitter generates a data symbol sequence known to the receiver. Once an agreed time has elapsed, the slicer output is used as a training signal and the actual data transmission begins. S88-4221 Seminar

  12. Stochastic gradient algorithm • The main idea is to minimize the mean square error between the output of the equalizer, and the transmitted signal. • Since the number of samples that the receiver observe is finite, mean square is calculated by using time averages instead of ensemble averages. • The resulting adaptation algorithm becomes; Error signal Received signal S88-4221 Seminar

  13. Stochastic gradient algorithm Error signal LINEAR EQUALIZER Trainning mode Decision directed mode + Channel Equalizer S88-4221 Seminar

  14. Feedback F(z) Output Feed forward C(z) + + Symbol decision Adjustment of filter coefficients Decision-Feedback Equalizers Decision feedback equalizer structure • The forward and feedback coefficients may be adjusted simultaneously to minimize the MSE. Input S88-4221 Seminar

  15. Feedback F(z) Output Feed forward C(z) + + Symbol decision Adjustment of filter coefficients Decision-Feedback Equalizers Input S88-4221 Seminar

  16. Evaluation 1 • Linear equalizer • LMS • Wiener solution • Scenarios • Channel 1 • Channel 2 ( Time varying channel) S88-4221 Seminar

  17. Evaluation 1- Linear Equalizer • Static Channel h = [0.2, -0.15, 1.0, 0.21, 0.03] • Lf=5 • Delay=4 • SNR=30dB S88-4221 Seminar

  18. Evaluation 1- Linear Equalizer • Static Channel h = [0.2, -0.15, 1.0, 0.21, 0.03] • Lf=12 • Delay=11 • SNR=30dB S88-4221 Seminar

  19. Evaluation 1 - Linear Equalizer • Time varying channel • Rayleigh • 5 taps, fd=10 Hz , Ts=0.8us • Lf=8 , mu=0.1 • Delay=7 • SNR=30dB S88-4221 Seminar

  20. Evaluation 1 - Linear Equalizer • Time varying channel • Rayleigh • 5 taps, fd=80 Hz , Ts=0.8us • Lf=8 , mu=0.1 • Delay=7 • SNR=30dB S88-4221 Seminar

  21. Evaluation 2 • Desicion feedback equalizer • LMS • Decision direct mode and trainning mode • Scenarios • Channel 1 h = [0.2, -0.15, 1.0, 0.21, 0.03] • Channel 2 h = [0.2, -0.35, 1.0, 0.51, 0.03] S88-4221 Seminar

  22. Evaluation 2 • Decision Feedback equalizer (static channel) Channel 2 Severe ISI Channel 1 S88-4221 Seminar

  23. Evaluation 3 • Decision Feedback equalizer • Rayleigh • 5 taps, fd=20 Hz , Ts=0.8us • Lf=8 , mu=0.015 ,Lfeed=5 • Delay=7 • SNR=30dB S88-4221 Seminar

  24. Evaluation 3 • Decision Feedback equalizer • Rayleigh • 5 taps, fd=80 Hz , Ts=0.8us • Lf=8 , mu=0.015 ,Lfeed=5 • Delay=7 • SNR=30dB S88-4221 Seminar

  25. Matlab examples S88-4221 Seminar

  26. Conclusions • Adaptive equalizer is an essential component of communication systems. • Low complexity implementation with a good performance in channel with low levels of ISI is obtained using linear equalizers. • In case of channels with severe ISI, DFE is the best option. S88-4221 Seminar

More Related