Pulse or digital communications – Equalizers – Automatic
Reexamination Certificate
1997-10-31
2001-09-04
Pham, Chi (Department: 2631)
Pulse or digital communications
Equalizers
Automatic
C708S323000
Reexamination Certificate
active
06285709
ABSTRACT:
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BACKGROUND OF THE INVENTION
A. Field of the Invention
The present invention relates to methods and apparatus for reducing distortions in sampled communication signals received over transmission media, and more particularly relates to error filtering in a hybrid equalizer system for generating an accurate estimate of the original transmitted signal.
B. Description of the Related Art
Linear and decision feedback equalizers are commonly used in communication receivers for computer systems providing applications such as multimedia, modem communications, optical and magnetic storage devices, and wireless systems. In high-speed modem data communication systems, it is often advantageous to incorporate an adaptive decision-feedback equalizer (hereafter referred to as DFE) in conjunction with an adaptive linear equalizer (hereafter referred to as LE). For computational efficiency, the least-mean-squares (LMS) algorithm is often used as a method for adapting the coefficients of the equalizers.
LE and DFE structures have been studied in detail for their simple structures and adequate performance over well-behaved channels. The DFE has enjoyed some success as a form of equalizer for data communication receivers that attempt to eliminate intersymbol interference (ISI), due to the DFE's simplicity and its ability, unlike the LE, to perform well over channels having spectral nulls, while advantageously providing a structure without noise enhancement. However, the fundamental problem with a LE/DFE system is that, for impairments that can be mitigated by either the LE or the DFE, deep convergence of the joint system is very slow, sometimes on the order of millions of symbol periods.
Equalizers may operate in a continuously adaptive mode to track variations in the communications channel. Such continuously adaptive modes, however, typically require a significant computational burden. A method of alleviating this computational overhead in a continuous adaptive mode is to adapt the equalizer coefficients periodically based upon a known training sequence. However, channel mismatch still occurs due to problems with periodic training and the like, and an inability to be optimized for considerable channel fluctuations. Computer simulations have been found useful for predicting channel fluctuations for equalizers, but the computational requirements still may be quite significant. As described in U.S. Pat. No. 4,985,902 to Gurcan for “Decision Feedback Equalizer and a Method of Operating a Decision Feedback Equalizer,” issued Jan. 15, 1991, a method attempts to optimize the peak reference tap of a DFE by optimizing the mean square error (MSE) performance of the DFE in the presence of arbitrary channel mismatch.
Gurcan makes the assumption that increasing the number of feed-forward taps improves the MSE performance. U.S. Pat. No. 5,513,214 to Gozzo for “System and Method of Estimating Equalizer Performance in the Presence of Channel Mismatch,” issued Apr. 30, 1996, however, indicates that while increasing the number of feed-forward taps may improve performance under ideal conditions, such is not always the case under severe channel mismatch conditions. Gozzo observes that existing performance estimators either found the MSE by ignoring channel mismatch, or calculated the MSE using cumbersome and/or expensive analysis or simulation techniques which are not amiable to real-time applications. Therefore, Gozzo attempts to provide quick estimation of equalizer performance under arbitrary channel mismatch conditions to predict the MSE performance of the LE or DFE structure when training the equalizers, assuming a finite length non-recursive type LE. Lee, “A Fast Computation Algorithm for the Decision Feedback Equalizer” IEEE Transactions on Communications, Vol. 43, No. 11, Nov. 1995, also describes a non-recursive MSE-DFE structure for achieving faster convergence. Such non-recursive LE solutions for estimating of equalizer performance using MSE estimation still require considerable computation capabilities.
Previous solutions to the rate of convergence problem have involved, either directly or by some approximation method, collecting data to determine an autocorrellation matrix, then the inversion of the autocorrellation matrix to extract initial coefficients. In directly inverting the autocorrellation matrix, extreme precision and intense computation are required, which becomes unrealistic for LE/DFE structures of some length in a real-time application. Other methods employ one or more approximations to the matrix inversion which adversely affect initial convergence, often achieving results inferior to simple joint LMS update. It would be desirable, therefore, to provide faster convergence of the LE and DFE coefficients using a recursive adaptation algorithm.
SUMMARY OF THE INVENTION
It is an object of the present invention to work on the disadvantages of prior art equalizer systems for generating accurate estimates of sampled communication signals received over transmission media.
It is another object of the present invention to provide error filtering in a hybrid equalizer system.
It is a further object of the present invention to provide apparatus and methods of compensating for distortions introduced in sampled communication signals received over a transmission medium to obtain accurate estimates of the original transmitted signals.
A described embodiment provides for the compensation of distortions introduced in high-speed data transmission signals received over a telephone network. An adaptive linear equalizer (LE) pre-filter is used for filtering incoming sampled communication signals received through the high-speed data transmission channel. An adaptive decision feedback equalizer (DFE) is used in conjunction with the LE to provide error filtering as a hybrid equalizer system to determine which of a plurality of communication states of the sampled communication signals is an accurate estimate of the originally transmitted signals over the transmission medium. An error signal is generated relative to the difference between the determined states of the decision mechanism of the DFE and the filtered communication signals from the LE. Further, an error filter provides a filtered output of the generated error signal, wherein the error filter has an error filter characteristic defined in accordance with the known telephone network transmission medium. The LE for the received sampled communication signals has a LE pre-filter characteristic defined in accordance with the filtered output of the error filter, using a recursive least-mean-square (LMS) technique. By filtering the error appropriately to each of the LE and DFE, using LMS update or any other convergent recursive tap update algorithm, significantly faster deep convergence of the joint structure may be achieved when the spectrum of the received signal is approximately known.
Briefly summarized, the present invention relates to apparatus and methods for compensating for distortions introduced in sampled communication signals received over a transmission medium. A pre-filter is used for filtering incoming communication signals received via the transmission medium. A decision mechanism is then used to determine which of a plurality of communication states of the sampled communication signals was originally transmitted over the transmission medium, responsive to the filtered communication signals from the pre-filter. An error signal generator generates an error signal relative to the difference between the determined states of the decision mechanism and the filtered communication signals from the pre-filter. Further, an error filter provides a filtered output of the error sig
Alelyunas Carl H.
Lery Scott A.
Norrell Andrew L.
Parizhsky Vladimir
3 Com Corporation
Bayard Emmanuel
McDonnell & Boehnen Hulbert & Berghoff
Pham Chi
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