Apparatus for, and method of, reducing power dissipation in a communications system

A method is provided for reducing power dissipation within a communications system having a plurality of adaptive filters with a plurality of taps, each tap is switchable between an active and an inactive state, each tap also has a coefficient. An acceptable error for the system is specified. This error is typically the mean squared error of the system. A tap threshold is set for each active tap. Those taps having a coefficient with an absolute value less than the tap threshold set for the active tap are deactivated. The error of the system is computed and compared to the acceptable system error. If the computed system error is less than the acceptable system error, the tap threshold for each active tap is increased. The process of comparing the tap coefficients to the tap thresholds, deactivating taps with a coefficient less than the tap threshold and computing the resulting system error is repeated until the computed system error approaches the acceptable system error without exceeding the acceptable system error. In addition, the previously deactivated taps may be periodically activated and their coefficients once again compared to the tap threshold. If a coefficient is less than the tap threshold the tap is again deactivated. If a coefficient is greater than the tap threshold, the tap remains active.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to systems for, and methods of, providing for the transmission and reception of signals through unshielded twisted pairs of wires within a communications system. The invention particularly relates to systems for, and methods of, reducing the power dissipation in devices within a communications system hand to systems for, and methods of, reducing such power dissipation in communications systems having high throughputs. A “high throughput” as used within the context of this disclosure may include, but is not limited to, one gigabit (GB) per second.

2. Description of Related Art

A basic communications system is illustrated in FIG.1. The system includes a hub and a plurality of computers serviced by the hub in a local area network (LAN). Four computers are shown by way of illustration but a different number of computers may be contained within the system. Each of the computers is usually displaced from the hub by a distance which may be as great as approximately one hundred meters (100 m.). The computers are also displaced from each other. The hub is connected to each of the computers by a communications line. Each communication line includes unshielded twisted pairs of wires or cables. Generally, the wires or cables are formed from copper. Four unshielded twisted pairs of wires are provided in each communication line between each computer and the hub. The system shown inFIG. 1is operative with several categories of unshielded twisted pairs of cables designated as categories 3, 4 and 5 in the telecommunications industry. Category 3 cables are the poorest quality (and lowest cost) and category 6 and 7 cables are the best quality (and highest cost).

Associated with each communications system is a “throughput”. The throughput of a system is the rate at which the system processes data and is usually expressed in bits/second. Most communications systems have throughputs of 10 megabits (Mb)/second or 100 Mb/second. A rapidly evolving area of communications system technology enables 1 Gb/second full-duplex communication over existing category-5 unshielded twisted pair cables. Such a system is commonly referred to as “Gigabit Ethernet.”

A portion of a typical Gigabit Ethernet is shown in FIG.2. The Gigabit Ethernet provides for transmission of digital signals between one of the computers and the hub and the reception of such signals at the other of the computer and the hub. A similar system can be provided for each of the computers. The system includes a gigabit medium independent interface (GMII) block which receives data in byte-wide format at a specified rate, for example 125 MHz, and passes the data onto the physical coding sublayer (PCS) which performs scrambling, coding, and a variety of control functions. The PCS encodes bits from the GMII into 5-level pulse amplitude modulation (PAM) signals. The five symbol levels are −2, −1, 0, +1, and +2. Communication between the computer and hub is achieved using four unshielded twisted pairs of wires or cables, each operating at 250 Mb/second, and eight transceivers, one positioned at each end of a unshielded twisted pair. The full-duplex bidirectional operation provides for the use of hybrid circuits at the two ends of each unshielded twisted pair. The hybrid controls access to the communication line, thereby allowing for full-duplex bidirectional operation between the transceivers at each end of the communications line.

A common problem associated with communications systems employing multiple unshielded twisted pairs and multiple transceivers is the introduction of crosstalk and echo noise or impairment signals into the transmission signals. Noise is inherent in all such communications systems regardless of the system throughput. However, the effects of these impairment signals are magnified in Gigabit Ethernet. Impairment signals include echo, near-end crosstalk (NEXT), and far-end crosstalk (FEXT) signals. As a result of these impairment signals the performance of the transceivers, particularly the receiver portion, is degraded.

NEXT is an impairment signal that results from capacitive and inductive coupling of the signals from the near-end transmitters to the input of the receivers. The NEXT impairment signals encountered by the receiver in transceiver A are shown in FIG.3. The crosstalk signals from transmitters B, C, and D appear as noise to receiver A, which is attempting to detect the direct signal from transmitter E. Each of the receivers in the system encounters the same effect and accordingly the signals passing through the receivers experience signal degradation due to NEXT impairment signals. For clarity ofFIG. 3, only the NEXT impairment experienced by receiver A is illustrated.

Similarly, because of the bidirectional nature of the communications systems, an echo impairment signal is produced by each transmitter on the receiver contained within the same transceiver as the transmitter. The echo impairment signal encountered by the receiver in each transceiver is shown in FIG.4. The crosstalk signals from transmitters appear as noise to the receivers, which are attempting to detect the signal from the transmitter at the opposite end of the communications line. Each of the receivers in the system encounters the same effect and accordingly the signals passing through the receivers experience signal distortion due to the echo impairment signal.

Far-end crosstalk (FEXT) is an impairment that results from capacitive coupling of the signal from the far-end transmitters to the input of the receivers. The FEXT impairment signals encountered by the receiver in transceiver A are shown in FIG.5. The crosstalk signals from transmitters F, G, and H appears as noise to receiver A, which is attempting to detect the direct signal from transmitter E. Each of the receivers in the system encounters the same effect and accordingly the signals passing through the receivers experience signal distortion due to the FEXT impairment signal. For clarity ofFIG. 5only the FEXT impairment experienced by receiver A is illustrated.

Four transceivers at one end of a communications line are illustrated in detail in FIG.6. The components of the transceivers are shown as overlapping blocks, with each layer corresponding to one of the transceivers. The GMII, PCS, and hybrid ofFIG. 6correspond to the GMII, PCS, and hybrid of FIG.2and are considered to be separate from the transceiver. The combination of the transceiver and hybrid forms one “channel” of the communications system. Accordingly,FIG. 6illustrates four channels, each of which operates in a similar manner. The transmitter portion of each transceiver includes a pulse-shaping filter and a digital-to-analog (D/A) converter. The receiver portion of each transceiver includes an analog-to-digital (A/D) converter, a first-in first-out (FIFO) buffer, a digital adaptive equalizer system including a feed-forward equalizer (FFE) and a detector. The receiver portion also includes a timing recovery system and a near-end noise reduction system including a NEXT cancellation system and an echo canceller. The NEXT cancellation system and the echo canceller typically include numerous adaptive filters.

Characteristics of the communication line, e. g., length, may impact the ability of the NEXT cancellation system and echo cancellers to effectively cancel NEXT and echo noise. Measurements of typical cable responses, as well as simulation, show that in order to provide an adequate level of cancellation of these sources of interference, “long” echo and NEXT cancellers are required. The term “long” is used to describe a canceller having a large number of taps as necessitated by the characteristics of the cable. For exampleFIG. 7shows the echo impulse response for a 100 m cable with a characteristic impedance of 85 ohm and 100 ohm terminations. Although the nominal characteristic impedance is 100 ohm, manufacturing standards allow for a 15% tolerance. The mismatch in impedance may result in a reflection at the far-end of the cable, which causes a secondary pulse with a delay of about one microsecond. Because of the long delay, cancelling this pulse requires an echo canceller with about 140 taps (125 taps to cover the one microsecond delay, plus approximately 15 additional taps to cancel the secondary pulse).

Often the echo impulse response has additional reflections at intermediate values of delay. In addition, structural return loss of the cable may cause continuous variations of the characteristic impedance along the cable, which results in a large number of smaller reflections at intermediate points. These intermediate reflections mean that the echo canceller should not be configured to cancel only the initial impulse and the end reflection but instead should be configured to cover the full span of the impulse response. Varying cable characteristics result in a wide variability of cable impulse responses. In addition, the response of a particular cable may change as a result of its operating environment. For example, a change in operating temperature may change the impulse response of the cable. Accordingly, it is difficult to precompute the locations at which taps are required and to build these locations into the design of the echo and NEXT cancellers.FIG. 8shows the NEXT impulse response for a 100 m cable. As indicated, the NEXT response can also be long, requiring a large number of taps in the NEXT cancellers which make up the NEXT cancellation system. The combination of the NEXT and echo cancellers consumes the majority of the DSP operations in a Gigabit Ethernet.

The large number of taps required to achieve a satisfactory performance in these systems results in high power dissipation. This high power dissipation is undesirable in that it may make high throughput communication systems, particularly Gigabit Ethernet, inoperable and unmarketable. Thus there exists a need in the art to provide a method of, and an apparatus for, reducing the power dissipation of communication systems employing a large number of taps and to provide a method of, and apparatus for, reducing such power dissipation in a high throughput system such a Gigabit Ethernet. The present invention fulfills these needs.

SUMMARY OF THE INVENTION

Briefly, and in general terms, the invention relates to systems for, and methods of, reducing the power dissipation in devices within a communications system and to systems for, and methods of, reducing such power dissipation in communications systems having high throughputs.

In one embodiment, the invention involves a method of reducing power dissipation in a communications system having a plurality of adaptive filters each having a plurality of taps. The method includes the steps of specifying a threshold error for the system and periodically adjusting the transfer function of at least one of the adaptive filters by selectively deactivating taps while ensuring that the error of the communications system does not exceed the threshold error.

In an additional facet of this embodiment of the invention the step of periodically adjusting the transfer function of at least one of the adaptive filters includes the step of determining whether to deactivate a tap. In another facet the step of determining whether to deactivate a tap includes the steps of computing the tap error produced by deactivating such tap and if the tap error is less than a prespecified acceptable level of tap error, deactivating the tap. In yet another aspect of the invention the step of determining whether to deactivate a tap includes the steps of computing the filter error produced by deactivating such tap and if the filter error is less than a prespecified acceptable level of filter error, deactivating the tap. In an still another facet, the step of determining whether to deactivate a tap comprises the steps of computing the system error produced by deactivating such tap and if the system error is less than the threshold error, deactivating the tap. In an additional aspect, the step of periodically adjusting the transfer function of at least one of the adaptive filters further includes the step of determining whether to activate a previously deactivated tap. In yet another facet, the step of determining whether to activate a previously deactivated tap includes the steps of periodically activating previously deactivated taps; computing the tap error produced by deactivating such taps; and if the tap error is less than a prespecified acceptable level of tap error, deactivating the tap.

In another embodiment, the invention involves a method for reducing power dissipation within a communications system having a plurality of adaptive filters with a plurality of taps, each tap switchable between an active and an inactive state, each having a coefficient. The method includes the steps of a) specifying an acceptable error for the system; b) for each active tap, setting a tap threshold; c) for each active tap, deactivating those taps having a coefficient with an absolute value less than the tap threshold set for the active tap; d) computing a system error; e) comparing the computed system error to the acceptable system error; f) if the computed system error is less than the acceptable system error, increasing the tap threshold for each active tap; and g) repeating steps c) through f) until the computed system error approaches the acceptable system error without exceeding the acceptable system error.

In another embodiment, the invention involves a method for reducing power dissipation within a communications system having at least one adaptive filter with a plurality of taps , each tap switchable between an active and an inactive state, each tap having a coefficient. The method includes the steps of a) computing an initial system error; b) for each active tap, setting a tap error threshold; c) for each active tap, deactivating those taps having a coefficient with an absolute value less than the tap error threshold set for the active tap; d) computing a subsequent system error; e) if the difference between the subsequent system error and the initial system error is less than a prespecified value, increasing the tap error threshold for each active tap; and f) repeating steps c) through e) until the difference between the subsequent system error and the initial system error exceeds the prespecified value.

In another embodiment, the invention is a communications system which includes a communications line and a plurality of adaptive filters responsive to signals carried by the communications line. Each adaptive filter has a plurality of taps each having a coefficient, each tap switchable between an active and an inactive state. The system also includes means for specifying a threshold error for the system, means for setting the state of each tap, means for calculating a present error for the system, and means for comparing the present error to the threshold error.

In an additional facet of this embodiment of the invention the means for setting the state of each tap includes means for specifying a tap threshold for each tap, means for comparing for each tap the absolute value of the tap coefficient with the tap threshold, and means for deactivating those taps having a coefficient with an absolute value less than the tap threshold. In yet another aspect, the means for setting the state of each tap further includes means for periodically activating previously deactivated taps.

In another embodiment, the invention involves a power dissipation reduction system for use in a communication system having at least one adaptive filter having a plurality of taps each having a coefficient, each tap switchable between an active and an inactive state. The power dissipation reduction system includes means for specifying a threshold error for the system; means for setting the state of each tap; means for calculating a present error for the system; and means for comparing the present error to the threshold error.

These and other aspects and advantages of the present invention will become apparent from the following more detailed description, when taken in conjunction with the accompanying drawings which illustrate, by way of example, the preferred embodiments of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The discussion in this specification may be considered to relate specifically to a Gigabit Ethernet for the purposes of explanation and understanding of the invention. However, it will be understood that the concepts of this invention and the scope of the claims apply to other types of communications systems than a Gigabit Ethernet.

A communications system incorporating the features of this invention is generally indicated at10in FIG.1. The system10includes a hub12and a plurality of computers serviced by the hub in a local area network (LAN). Four computers14are shown by way of illustration but a different number of computers may be used without departing from the scope of the invention. Each of the computers14may be displaced from the hub12by a distance as great as approximately one hundred meters (100 m.). The computers14are also displaced from each other.

The hub12is connected to each of the computers14by a communications line16. The communication line16comprises a plurality of unshielded twisted pairs of wires or cables. Generally, the wires or cables are formed from copper. Four unshielded twisted pairs of wires are provided in the system10between each computer and the hub12. The system shown inFIG. 1is operative with several categories of twisted pairs of cables designated as categories 3, 4 and 5 in the telecommunications industry. Category 3 cables are the poorest quality (and lowest cost) and category 5 cables are the best quality (and highest cost). Gigabit Ethernet uses category 5 cables.

FIG. 2illustrates, in detail, a portion of the communications system ofFIG. 1including one communications line16and portions of one of the computers14and the hub12. The communications line16includes four unshielded twisted pairs of wires18operating at 250 Mb/second per pair. A transceiver20, including a transmitter (TX)22and receiver (RX)24, is positioned at each unshielded end of each twisted pair18. Between each transceiver20and its associated unshielded twisted pair18is a hybrid26. The hybrid26is the interface to the communication line16which allows for full-duplex bidirectional operation between the transceivers20at each end of the communications line. The hybrid also functions to isolate the transmitter and receiver associated with the transceiver, from each other.

The communications system includes a standard connector designated as a gigabit media independent interface (GMII). The GMII may be an eight bit wide data path in both the transmit and receive directions. Clocked at a suitable frequency, such as 125 MHz, the GMII results in a net throughput in both directions of data at a suitable rate such as 250 Mb/second per pair. The GMII provides a symmetrical interface in both the transmit and receive directions. A physical coding sublayer (PCS)30receives and transmits data between the GMII28and the transceivers20. The PCS30performs such functions as scrambling and encoding/decoding data before forwarding the data to either the transceiver or the GMII. The PCS encodes bits from the GMII into 5-level pulse amplitude modulation (PAM) signals. The five symbol levels are −2, −1, 0, +1, and +2. The PCS also controls several functions of the transceivers, such as skew control as explained below.

Four of the transceivers20are illustrated in detail in FIG.9. The components of the transceivers20are shown as overlapping blocks, with each layer corresponding to one of the transceivers. The GMII28, PCS30, and hybrid26ofFIG. 9correspond to the GMII, PCS, and hybrid of FIG.2and are considered to be separate from the transceiver. The combination of the transceiver20and hybrid26forms one “channel” of the communications system. Accordingly,FIG. 9illustrates four channels, each of which operate in a similar manner. Features of the communications system ofFIG. 9are disclosed in the following copending patent applications, each of which is assigned of record to the assignee of record of this application Ser. No. 09/037,328, filed Mar. 9, 1998, entitled APPARATUS FOR, AND METHOD OF, REDUCING NOISE IN A COMMUNICATIONS SYSTEM, inventor Oscar E. Agazzi; Ser. No. 09/078,466, filed May 14, 1998, entitled STARTUP PROTOCOL FOR HIGH THROUGHPUT COMMUNICATIONS SYSTEMS, inventors Oscar E. Agazzi and John L. Creigh; and Ser. No. 09/078,933, filed May 14, 1998, entitled STARTUP PROTOCOL FOR HIGH THROUGHPUT COMMUNICATIONS SYSTEMS, inventor Oscar E. Agazzi.

The transmitter portion of each transceiver20includes a pulse shaping filter32and a digital to analog (D/A) converter34. In a preferred embodiment of the invention the D/A converter34operates at 125 MHz. The pulse shaping filter32receives one one-dimensional (1-D) symbol from the PCS. This symbol is referred to as a TXDatax symbol36, where x is 1 through 4 corresponding to each of the four channels. The TXDatax symbol36represents 2 bits of data. The PCS generates one 1-D symbol for each of the channels. The symbol for each channel goes through a spectrum shaping filter of the form 0.75+0.25 z−1at the pulse shaping filter32to limit emissions within FCC requirements. This simple filter shapes the spectrum at the output of the transmitter so that its power spectral density falls under that of communications systems operating at 100 Mb/second on two pairs of category −5 twisted pair wires. The symbol is then converted into an analog signal by the D/A converter34which also acts as a lowpass filter. The analog signal gains access to the unshielded twisted pair wire18through the hybrid circuitry26.

The receiver portion of each transceiver includes an A/D converter42, a FIFO44, a digital adaptive equalizer system, a timing recovery circuit and noise reduction circuitry. The digital adaptive equalizer system includes a feed-forward equalizer (FFE)46, two devices50,56, a skew adjuster54and two detectors58,60. The functions of these components, as related to the present invention, are explained below. The general concept of the use of a digital adaptive equalizer in a communications system is disclosed in U.S. Pat. No. 5,604,741 to Samueli et al. entitled ETHERNET SYSTEM. The noise reduction circuitry includes a NEXT cancellation system38, an echo canceller40, and a FEXT cancellation system70.

The A/D converter42provides digital conversions of the signals received from the hybrid26at a suitable frequency, such as 125 MHz , which is equal to the baud rate of the signals. The A/D converter42samples the analog signals in accordance with an analog sample clock signal78provided by the decision-directed timing recovery circuit64. The FIFO44receives the digital conversion signals from the A/D converter42and stores them on a first-in-first-out basis. The FIFO forwards individual signals to the FFE46in accordance with a digital sample clock signal80provided by the timing recovery circuit64. The feed forward equalizer (FFE)46receives digital signals from the FIFO and filters these signals. The FFE46is a least mean squares (LMS) type adaptive filter which performs channel equalization and precursor inter symbol interference (ISI) cancellation to correct for distortions in the signal.

It should be noted that the signal introduced into the A/D converter42and subsequently into the FIFO44and FFE46has several components. These components include the direct signal received directly from the transmitter22at the opposite end of the unshielded twisted pair wire18with which the receiver24is associated. Also included are one or more of the NEXT, echo, and FEXT impairment signals from other transmitters22as previously described. The signal including the direct signal and one or more of the impairment signals is referred to as a “combination signal.”

The FFE46forwards the combination signal48to a second device50, typically a summing device. At the second device50the combination signal48is combined with the outputs of the NEXT cancellation system38and echo canceller40to produce a signal which is substantially devoid of NEXT and echo impairment signals. This signal is referred to as a “first soft decision”52. The skew adjuster54receives the first soft decision52from the second device50and outputs a signal referred to as a “second soft decision”66. The skew adjuster54performs two functions. First, it compensates for the difference in length of the unshielded twisted pairs18by delaying the first soft decision52so that the second soft decisions66from all of the receivers in the system are in sync. Second, it adjusts the delay of the first soft decision52so that the second soft decision66arrives at the first device56at substantially the same time as the output of the FEXT cancellation system70. The skew adjuster54receives skew control signals82from the PCS30.

The skew adjuster54forwards the second soft decision66to a first device56, typically a summing device. At the first device56the second soft decision66is combined with the output of the FEXT cancellation system70to produce a signal which is substantially devoid of FEXT impairment signals. This signal is referred to as a “third soft decision”68. The first detector58receives the third soft decision68from the first device56. The first detector58provides an output signal, i.e., a “final decision”72. The detector may be a slicer which produces a final decision72corresponding to the analog signal level closest in magnitude to the level of the third soft decision68. The detector may also be either a symbol-by-symbol detector or a sequential detector which operates on sequences of signals across all four channels simultaneously, such as a Viterbi decoder.

In one embodiment the first detector58is a symbol-by-symbol detector. A group of symbol-by-symbol detectors58, one for each channel, is shown in FIG.10. Each first detector58includes a slicer98, adaptive feedback filter100and an adder102. The adder102combines the third soft decision68with the output of the adaptive feedback filter100to provide an output which is introduced to the slicer98. The output of the slicer98in introduced to the adaptive feedback filter100. The first detector58provides an output signal72which corresponds to the discrete level from the set [−2, −1, 0, 1, 2] which is closest to the difference between the third soft decision68and the output of the feedback filter100. The adaptive feedback filter100corrects for distortion in the third soft decision68. This filter100uses past slicer98decisions to estimate postcursor ISI caused by the channel. This ISI is canceled from the third soft decision68to form the final decision signal72.

In another embodiment the first detector58is a combination of a sequential decoder with a decision feedback equalizer (DFE) using the architecture usually known as multiple DFE architecture (MDFE) sequential detector. The sequential decoder58looks at all signals from all four channels at the same time and at successive samples from each channel over several periods of unit time. A sequential decoder receives as input at least one signal from each of the first devices56. The sequential decoder58, in general, is responsive to the sequences of the output signals from the first devices56for (1) passing acceptable sequences of such signals and (2) discarding unacceptable sequences of such signals in accordance with the constraints established by the code standard associated with the system. Acceptable sequences are those which obey the code constraints and unacceptable sequences are those which violate the code constraints.

The second detector60(FIG. 9) receives the first soft decision52from the second device50. The second detector60is a symbol-by-symbol detector. It provides an output signal74which corresponds to the discrete level from the set [−2, −1, 0, 1, 2] which is closest to the difference between the first soft decision52and the output of the feedback filter100. The second detector60produces output signals74without the benefit of FEXT cancellation, as a result, these decisions have a higher error rate than those made by the first detector58, which enjoys the benefits of FEXT cancellation. Because of this fact, these decisions are called “tentative decisions”. It is important to note that the postcursor ISI present in the input to the second detector60is canceled using the adaptive feedback filter100, (FIG. 10) contained within the second detector, whose inputs are the tentative decisions74. The coefficients of this adaptive feedback filter100are the same as those of the adaptive feedback filter associated with the first detector58(FIG.9).

A third device62, typically a summing device, receives the first soft decision signal52from the second device50and the tentative decision signals74from the second detector60. At the third device62the first soft decision52is combined with the tentative decision signal74to produce an error signal76which is introduced into the timing recovery circuit64. The timing recovery circuit64receives the tentative decision74from the second detector60and the error signals76from the third device62. Using these signals as inputs the timing recovery circuit64outputs an analog clock sync signal78which is introduced to the A/D converter42and a digital clock sync signal80which is introduced into the FIFO44. As previously mentioned, these signals control the rate at which the A/D converter42samples the analog input it receives from the hybrid26and the rate at which the FIFO forwards digital signals to the FFE46. A suitable timing recovery device for use in the present invention is disclosed in copending patent application Ser. No. 08/970,557, filed Nov. 14, 1997, entitled APPARATUS FOR, AND METHOD OF, PROCESSING SIGNALS TRANSMITTED OVER A LOCAL AREA NETWORK, inventors Henry Samueli, Fung Lu and Avanindra Madisetti and assigned of record to the assignee of record of this application.

As mentioned before, the symbols sent by the transmitters22(FIG. 2) in the communications system cause NEXT, echo and FEXT impairments in the received signal for each channel. Since each receiver24has access to the data for the other three channels that cause this interference, it is possible to nearly cancel each of these effects. NEXT cancellation is accomplished using three adaptive NEXT cancelling filters as shown in the block diagram of FIG.11. Each NEXT cancellation system38receives three TXDatax symbols36from each of the transmitters at the same end of the communications line18as the receiver with which the NEXT cancellation system is associated. Each NEXT cancellation system38includes three filters84, one for each of the TXDatax symbols36. These filters84model the impulse responses of the NEXT noise from the transmitters and may be implemented as adaptive transversal filters (ATF) employing, for example, the LMS algorithm. The filters84produce a replica of the NEXT impairment signal for each TXDatax symbol36. A summing device86combines the three individual replica NEXT impairment signals92to produce a replica of the NEXT impairment signal contained within the combination signal received by the receiver with which the NEXT cancellation system38is associated. The replica NEXT impairment signal88is introduced into the second device50(FIG. 9) where it is combined with the combination signal48to produce a first soft decision signal52which is substantially devoid of NEXT impairment signals.

Echo cancellation is accomplished with an adaptive cancelling filter85as shown in the block diagram of FIG.12. Each echo canceller40receives the TXDatax symbols36from the transmitter at the same end of the twisted wire pair18as that of the receiver with which the echo canceller is associated. As shown inFIG. 9, each echo canceller40includes one filter85. These filters85model the impulse responses of the echo noise from the transmitter and may be implemented as ATFs employing, for example, the LMS algorithm. The filter produces a replica of the echo impairment signal contained within the combination signal received by the receiver with which the echo canceller40is associated. The replica echo impairment signal90is introduced into the second device50(FIG. 9) where it is combined with the combination signal48to produce the first soft decision signal52which is substantially devoid of echo impairment signals.

FEXT cancellation is accomplished with three adaptive FEXT cancelling filters87as shown in the block diagram of FIG.13. Each FEXT cancellation system70receives three tentative decision symbols74one from each of the receivers at the same end of the communications line as the receiver with which the FEXT cancellation system is associated. Each FEXT cancellation system70includes three filters87, one for each of the tentative decision symbols74. These filters87model the impulse responses of the FEXT noise from transmitters and may be implemented as ATFs employing, for example, the LMS algorithm. The filters87produce a replica of the FEXT impairment signal96for each individual tentative decision symbol74. A summing device108combines the three individual replica FEXT impairment signals96to produce a replica of the FEXT impairment signal contained within the combination signal48received by the receiver with which the FEXT cancellation system is associated. The replica FEXT impairment signal94is introduced into the first device56(FIG. 9) where it is combined with the second combination signal66to produce the third soft decision signal68which is substantially devoid of FEXT impairment signals. It is important to note that the higher error rate of the tentative decisions74does not degrade the performance of the FEXT cancellation system70, because the decisions used to cancel FEXT are statistically independent from the final decisions72made by the receiver whose FEXT is being canceled. Details of a FEXT cancellation system are disclosed in copending patent application Ser. No. 09/037,328, filed Mar.9,1998, entitled APPARATUS FOR, AND METHOD OF, REDUCING NOISE IN A COMMUNICATIONS SYSTEM, inventor Oscar E. Agazzi and assigned of record to the assignee of record of this application.

The symbols provided by the first detector58are decoded and descrambled by the receive section of the PCS30before being introduced to the GMII. Variations in the way the wire pairs are twisted may cause delays through the four channels by up to 50 nanoseconds. As a result, the symbols across the four channels may be out of sync. As previously mentioned, in the case where the first detector is a sequential detector, the PCS also determines the relative skew of the four streams of 1-D symbols and adjusts the symbol delay, through the skew adjuster54, prior to their arrival at the first detector58so that sequential decoder can operate on properly composed four-dimensional (4-D) symbols. Additionally, since the cabling plant may introduce wire swaps within a pair and pair swaps among the four unshielded twisted pairs, the PCS30also determines and corrects for these conditions.

As previously mentioned, the NEXT cancellation system, echo canceller and FEXT cancellation system use ATFs to effectively cancel the noise from the combination signal. An example of an ATF which may be employed by the present invention is shown in FIG.14and is further disclosed in copending patent application Ser. No. 60/107,877, filed Nov. 9, 1998 entitled DIRECT-TRANSPOSED FILTER, inventor Mehdi Hatamian and assigned of record to the assignee of record of this application. The ATF120includes a plurality of taps122each including a multiplier124and an adder126. Associated with each tap122is a coefficient Cn, where n is 0 through x−1 where x is the number of taps in the ATE. The circuitry associated with each tap122includes a 1-bit storage (not shown) that allows for activation and deactivation of the tap. The values of the coefficients Cn are adjusted in accordance with an LMS algorithm as mentioned before. Interposed between the taps122are registers128. These registers128provide data to the taps122at timed intervals in accordance with a clock signal. A suitable register128for use in the present invention is disclosed in copending patent application Ser. No. 60/107,878, filed Nov. 9, 1998, entitled STATIC-DYNAMIC REGISTER, inventor Mehdi Hatamian and assigned of record to the assignee of record of this application.

The impulse responses of an echo and NEXT, as shown inFIGS. 7 and 8, indicates that not all taps122in the NEXT and echo cancellers38,40are contributing significantly to the performance of the communications system. The present invention determines what taps122are not contributing significantly to the reduction of the mean squared error (MSE) of the system and deactivates these taps, thereby eliminating them from the filtering computation and thus reducing considerably the power dissipation of the system. Furthermore, as shown by the impulse response ofFIGS. 7 and 8, the need to build NEXT and echo cancellers38,40with a long span is difficult to avoid. Specific cable responses may differ from the one depicted inFIGS. 7 and 8, and accordingly require more or fewer taps122than that required for the cable ofFIGS. 7 and 8. As mentioned before it is difficult to determine a priori what taps122are needed with a particular cable.

In accordance with the present invention, the NEXT, echo, and FEXT cancellers38,40,70are configured with ATFs120which employ a sufficient number of taps122to provide adequate cancellation with the worst-case expected impulse responses. This may require140taps122as in the example ofFIG. 7, or even more for longer cables. To reduce the power dissipation, the taps122are examined after convergence, and those taps that are found not to contribute significantly to the performance of the system are deactivated. When the tap122is deactivated, it is removed from the NEXT, echo and FEXT replica computation and from the adaptation and its contribution to the overall power dissipation of the system is substantially eliminated.

When the system is initially converged, all taps122are active, so the NEXT, echo and FEXT cancellers38,40,70are converged along their entire length. After convergence, the taps122are examined to determine which ones can be deactivated using the tap scanning algorithm depicted in FIG.15. At step S1, an acceptable level of error for the system Seais specified. At step S2, a tap coefficient threshold Tthis set for each active tap. While each individual tap may have a unique tap threshold Tth, in a preferred embodiment of the invention the tap thresholds for all taps are substantially the same. The initial value of the tap coefficient threshold Tthis sufficiently low such that only a few taps122are deactivated and the performance of the system is not significantly affected. In a preferred embodiment of the invention, the tap coefficient threshold Tthis initially set equal to the tap coefficient Cnhaving the minimum absolute value. Alternatively, a reasonable value can be determined by simulation. This initial value is not critical, as long as it is sufficiently low to avoid a large degradation of the performance of the system the first time the tap scanning procedure is applied.

At step S3, the absolute value of the tap coefficient Cnfor each active tap is compared to the tap coefficient threshold Tth. If the tap coefficient Cnis less than the tap coefficient threshold Tththe tap122is deactivated at step S4. This process is repeated for each tap122in the filter120. Preferably, the determination of whether to deactivate a tap122is done in a sequential manner starting at the input end of the filter120. At step S5, the error for the system Secis computed. This error is computed by first computing the MSE for each active tap122by multiplying the absolute value of the tap coefficient Cnby the average energy signal. The error of the filter120associated with the tap122is determined by summing the individual tap errors. The error of the system is then determined by summing the individual filter errors.

In step S6, the computed system error Secis compared to the specified acceptable system error Sea. If the computed system error Secis less than the acceptable system error Sea, the tap threshold Tthfor each active tap is increased by a small amount at step S7and steps S3through S6are repeated. As a result, some additional taps122are deactivated, but the number of taps deactivated is usually not very large because of the small increase in the tap threshold Tth. Steps S3through S6are repeated until the computed system error Secapproaches the acceptable system error Seawithout exceeding the acceptable system error. If the computed system error Secis greater than the acceptable system error Sea, the tap scanning algorithm stops.

As an alternative to determining whether to deactivate a tap based on the MSE of the communications system, a determination may be made based on the MSE of an individual filter. In this embodiment of the invention an acceptable level of error for a filter Feais specified. Individual taps are deactivated, as previously described, and a computed filter error Fecis calculated. If the deactivation of a tap does not cause the computed filter error Fecto exceed the acceptable filter error Feathe tap remains inactive.

In yet another embodiment, the contribution of each deactivated tap to the MSE of the filter and, in turn, the system is calculated. If the MSE contribution of the tap is determined to be an acceptable amount the tap remains deactivated. This method is generally preferred during the initial startup of the system when the overall MSE of the system is large due to the nonconverged state of the filter coefficients within the system. Once the filter coefficients of the system have initially converged, the determination of whether to deactivate a tap is generally made based on the taps contribution to the MSE of the system as previously described with reference to FIG.15.

The final result of the tap scanning algorithm is that, in typical channels of the communication system, a large number of taps122is deactivated, and power dissipation is reduced by a large factor. As an example, computer simulations of the tap scanning algorithm when operating on the channel whose echo response is shown inFIG. 7are presented in FIG.16. This figure shows both the master and slave MSE to signal ratios as a function of time during the initial convergence of the system. At time t=360,000 bauds, the tap scanning algorithm begins, and as a result the MSE to signal ratio increases to the prespecified target of 24 dB.FIG. 17shows the taps of the echo canceller after convergence with a threshold of 24 dB andFIG. 18shows the taps with a threshold of 26 dB. The deactivated taps are shown as zeros. InFIG. 17, the total number of active taps for the echo canceller is twenty-two. Similarly, the number of active taps122for the three NEXT cancellers (not shown) forming the NEXT cancellation system is six, two, and zero, respectively. InFIG. 18, the total number of active taps for the echo canceller is forty-seven. Similarly, the number of active taps122for the three NEXT cancellers (not shown) is six, two, and zero, respectively.

For the case of the 24 dB threshold, out of 440 initially active taps, only 30 remain active after the application of the tap scanning algorithm, while maintaining a 5 dB margin for required bit error rate. Notice fromFIGS. 17 and 18that those taps122which remain active occur at sparse locations, and it would have been difficult to statically allocate these taps during the design of the NEXT and echo cancellers, because the location of taps is highly dependent on the specific cable response.

In another embodiment of the invention, the tap scanning algorithm monitors the change in MSE as the tap scanning algorithm progresses. The algorithm is applied until the change in MSE—rather than the MSE itself—exceeds a prespecified value, for example 1 dB. If the MSE to signal ratio before the scanning is applied is 25 dB, the final MSE to signal ratio is 24 dB, and a large number of taps is deactivated. This embodiment of the tap scanning algorithm is depicted in FIG.19. In step S10, the initial system error is Seicomputed. In step S11, an acceptable system error differential Deis specified. In step S12, a tap coefficient threshold Tthis set for each active tap. As with the other tap scanning algorithm, the initial value of the tap threshold Tthis sufficiently low such that only a few taps122are deactivated and the performance of the system is not significantly affected.

At step S13, the absolute value of the tap coefficient Cn, for each active tap is compared to the tap coefficient threshold Tth. If the tap coefficient Cnis less than the tap coefficient threshold Tththe tap122is deactivated at step S14. This process is repeated for each tap122in the filter120. Preferably, the determination of whether to deactivate a tap122is done in a sequential manner starting at the input end of the filter120. At step S15, the subsequent error for the system Sesis computed.

In step S16, the subsequent error for the system Sesis compared to the to the initial system error is Sei. If the difference between the subsequent system error Sesand the initial system error Seiis less than a prespecified value, the tap threshold Tthis increased by a small amount at step S17and steps S13through S16are repeated. As a result, some additional taps122are deactivated. Steps S13through S16are repeated until the difference between the subsequent system error Sesand the initial system error Seiexceeds the prespecified value.

In some cases the impulse responses of NEXT, echo and FEXT may change during normal operation, for example as a result of temperature changes. It is therefore desirable to periodically activate previously deactivated taps122, preferably in a sequential manner, and recheck if the absolute value of the tap coefficient Cnis below the tap threshold Tth. If a tap coefficient Cnhas grown to a value above the tap threshold Tth, the tap122remains active, otherwise it is deactivated. Similarly, those taps122that were active may fall below the tap threshold Tth, in which case they are deactivated. All this can be accomplished with a periodic reapplication of the sequential tap scanning algorithm during normal operation.

In an alternate embodiment of the invention a select number of taps122, for example ten, positioned at the input end of the filter120are not subject to deactivation. Usually there is a large slew rate in these first few taps122, which means that their numerical value could change significantly if the sampling phase changes. This sampling phase could change dynamically as a result of jitter, causing some previously deactivated taps122to become significant. By maintaining a number of taps122at the input end of the filter in an active state, potential degradations in the presence of jitter are avoided.

When the total number of taps is very large, for example 440, the power dissipation could be large during the initial convergence transient before the tap scanning algorithm has had a chance to deactivate the taps. Although the average power dissipation of the system is still greatly reduced, the peak power is not. A preferred embodiment of the invention compensates for this by converging the NEXT, echo and FEXT cancellers in stages. For example, a block of 20 taps is converged at a time, and the tap scanning algorithm is then applied to these taps on a per-block basis. In cases where the MSE during the initial convergence is large, for example as a result of the fact that the initial block of 20 taps may not be large enough to provide a lower MSE, it may be better to monitor the sum of the squared values of the coefficients of deactivated taps122as a measure of whether the algorithm can be terminated.

Although this invention has been disclosed and illustrated with reference to particular embodiments, the principles involved are susceptible for use in numerous other embodiments which will be apparent to persons of ordinary skill in the art. The invention is, therefore, to be limited only as indicated by the scope of the appended claims.