Adaptive noise filtering and equalization for optimal high speed multilevel signal decoding

Information

  • Patent Grant
  • 7035361
  • Patent Number
    7,035,361
  • Date Filed
    Tuesday, July 15, 2003
    21 years ago
  • Date Issued
    Tuesday, April 25, 2006
    18 years ago
Abstract
A Signal Conditioning Filter (SCF) and a Signal Integrity Unit (SIU) address the coupled problem of equalization and noise filtering in order to improve signal fidelity for decoding. Specifically, a received signal can be filtered in a manner to optimize the signal fidelity even in the presence of both significant (large magnitudes of) ISI and noise. The present invention can provide an adaptive method that continuously monitors a signal fidelity measure. Monitoring the fidelity of a multilevel signal can be performed by external means such as by the SIU. A received signal y(t) can be “conditioned” by application of a filter with an electronically adjustable impulse response g(t). A resulting output z(t) can then be interrogated to characterize the quality of the conditioned signal. This fidelity measure q(t) can be used to adjust the filter response to maximize the fidelity measure of the conditioned signal.
Description
FIELD OF THE INVENTION

The present invention relates to communication systems and improving the received signal quality in a high-speed communications environment through the use of equalization. The improvement in signal quality affords gains in system performance such as increased data throughput capacity or reduced error rate. Specifically, the present invention relates to a method and system for improving the quality of a received signal by counteracting distortions introduced in signal generation, transmission, and reception.


BACKGROUND OF THE INVENTION

Network bandwidth consumption is rising at a rapid rate. Existing network capacity is marginally adequate and is expected, as of this writing, to soon be inadequate. Thus, there is a need to increase network bandwidth capacity. This increase in bandwidth can be achieved by increasing the symbol transmission rate to yield a corresponding increase in the data rate or by using advanced modulation techniques with higher spectral efficiency (i.e. techniques that communicate more than one information bit per symbol).


Regardless of the technique employed to achieve higher data throughput, the higher data throughput can place more stringent requirements on the fidelity of the signal communicated. Fidelity of the signal communicated can be hampered by signal degradation. Signal degradation can occur during signal generation and signal transmission. Signal degradation incurred in generating and transmitting a signal over a channel can largely be categorized as arising from two sources: (i) filtering of the signal and (ii) corruption from noise.


In classical communications (e.g. wireless or wireline communications), the noise component is commonly addressed by using optimal detection (i.e. matched-filtering followed by optimal thresholding). However, such a conventional approach often neglects the inter-symbol interference (ISI) associated with the filtering that occurs in the channel, i.e. that approach assumes that the noise is the dominant source of distortion. If the ISI is the dominant source of signal degradation, then the conventional approach is to equalize the channel, e.g. filter the received signal with an inverse filter prior to detection. The use of any one of these approaches in isolation may not improve signal fidelity since matched-filtering and equalization are often contradicting goals.


For example, equalization generally corresponds to high-pass filtering which, while removing ISI, increases the presence of high-frequency noise. A low-pass filter (LPF) is usually employed to the equalized signal in order to reduce the effect of the high-frequency noise but which also re-introduces ISI. Matched-filtering, on the other hand, is often low-pass in nature and thus frequently exacerbates the ISI in the signal in the process of reducing noise.


The separate application of matched-filtering and equalization can be characterized as “ad-hoc” because it does not consider the problem of noise mitigation and equalization in a combined framework, and thus, neglects the impact each has on the other.


There exist techniques in the conventional art which address noise mitigation and equalization in a common framework. In particular, the well-known Least-Mean Squares (LMS) based approaches minimize a distortion measure that captures the impact of both noise and ISI. Furthermore, these methods are adaptive in the sense that the settings of the filter are automatically adjusted to the optimal value. This adaptive feature is often necessary as the exact characteristics of the channel distortion and noise spectral content vary from installation to installation and also with time and temperature in some instances.


Unfortunately, the use of these traditional adaptive LMS-based control methodologies for high-data rate systems can be impractical due to data acquisition and processing difficulties. In particular, it can be economically impractical (and often technically infeasible) to (i) produce the analog-to-digital converters (ADC's) capable of digitizing the signal at the required speed and resolution and (ii) produce a processor capable of handling the digitized data at the high speeds.


Therefore, there is a need in the art for an adaptive filtering approach that combines channel equalization and noise filtering. Another need exists in the art for a method and system for high speed digital communications that combines channel equalization and noise filtering in a single framework and that can account for the effects that equalization can have on noise filtering, and vice-versa. Additionally, there is a need for such a method and system which is economically and technically practical for high-speed data systems.


SUMMARY OF THE INVENTION

A Signal Conditioning Filter (SCF) and a Signal Integrity Unit (SIU) can control elements that filter a digital (i.e. binary or multilevel) signal. A multilevel signal uses discrete amplitudes, which can change from one time interval to another, to convey information in each time interval. The simplest example of multilevel signaling is binary signaling where two amplitudes are used to represent a logical 0 or 1 (i.e. one bit of information). By using more levels, more information can be conveyed with each symbol or in each time interval. In some of the prior art and conventional art, the term “multilevel” conveys the use of more than two amplitude levels. To avoid any ambiguity, the term “digital signaling” will be used in this writing to refer to signaling with discrete amplitudes and time intervals, i.e. digital signaling that can include both binary and multilevel signaling.


The SCF and SIU form part of a method and system for equalizing and filtering a digital signal. This method and system for equalizing and filtering may be used in a variety of high-speed communications systems. Applications can include, but are not limited to, (i) electrical systems such as backplane, telecom, and datacom systems and (ii) optical systems such as long-haul, metro, and short-reach applications.


Regardless of the application, the method and system can process a received digital signal in the electrical domain prior to decoding. Thus, in optical systems, the method and system can be used either after photodetection in the receiver or prior to modulation in the transmitter.


The present invention can address the coupled problem of equalization and noise filtering in order to improve signal fidelity for decoding. Specifically, a received digital signal can be filtered in a manner to optimize the signal fidelity even in the presence of both significant (large magnitudes of) ISI and noise. Furthermore, the method and system of the present invention can be adaptive in the sense that filter coefficients can be continuously updated to reflect any time-varying changes in the system characteristics.


The present invention can provide an adaptive method that continuously monitors a signal fidelity measure. For example, monitoring the fidelity of a digital signal can be performed by external means such as a Signal Integrity Unit (SIU). A received signal y(t) can be “conditioned” by application of a filter with an electronically adjustable impulse response g(t). A resulting output z(t) can then be interrogated to characterize the quality of the conditioned signal.


This fidelity measure q(t) can then be fed back to the SCF. Utilizing the signal fed back to the SCF, the response of the SCF can be adjusted to maximize the received fidelity measure. For the SIU, the signal fidelity measure can be directly associated with a decision error probability in a subsequent decoder with optimal decision thresholds. Combining the proposed approach with such a control system can balance (in a principled fashion) the trade-off between the degree to which ISI is corrected and noise is mitigated for optimal decoding.


The SCF can include a cascade of two or more tapped delay line filters with electronically controllable gain coefficients. The tap spacings of the two filters can be different in order to effectively combat both the effect of ISI which occurs on a large time scale and the effects of noise, jitter, and signal ringing which occur on a small time scale.


Using a cascade of two distinct filters can minimize the number of taps required to address both of these phenomena. The delay lines in these filters can include artificial transmission lines which can absorb the parasitic capacitance of the tap amplifiers. The tap amplifiers which vary the gain coefficients can be implemented using special Gilbert cell multipliers.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1A illustrates a digital signal receiver architecture according to one exemplary embodiment of the present invention.



FIG. 1B illustrates a signal integrity unit according to one exemplary embodiment of the present invention.



FIG. 2 illustrates an equalization architecture according to one exemplary embodiment of the present invention.



FIG. 3 illustrates a short-time filter and a long-time filter that form a signal conditioning filter according to one exemplary embodiment of the present invention.



FIG. 4 illustrates a short-time filter in the form of a tapped-delay line filter with small tap delays less than a symbol period of a digital signal according to one exemplary embodiment of the present invention.



FIG. 5. illustrates a long-time filter in the form of a tapped-delay line filter with delays substantially equal to the symbol period according to one exemplary embodiment of the present invention.



FIG. 6 illustrates a signal conditioning filter (SCF) forming part of a communications transmitter according to one exemplary embodiment of the present invention.



FIG. 7 is a functional block diagram illustrating a tapped-delay line filter according to one exemplary embodiment of the present invention.



FIG. 8 is a functional block diagram illustrating a tapped-delay line filter and one of the exemplary signal paths according to one exemplary embodiment of the present invention.



FIG. 9 is a functional block diagram illustrating a variable gain tap amplifier according to one exemplary embodiment of the present invention.



FIG. 10 is a circuit diagram illustrating a lumped LC delay line that has terminations provided on either end according to one exemplary embodiment of the present invention.



FIG. 11 is a circuit diagram illustrating an three-tap tapped-delay line filter having variable gain amplifiers described in FIG. 18 and delay blocks described in FIG. 19 according to one exemplary embodiment of the present invention.



FIG. 12 is a circuit diagram of a variable gain tap amplifier according to one exemplary embodiment of the present invention.



FIG. 13 is a circuit diagram of 5-tap tapped-delay line filter with artificial transmission lines according to one exemplary embodiment of the present invention.



FIG. 14 is a circuit diagram of an exemplary long-time delay artificial transmission line according to one exemplary embodiment of the present invention.



FIG. 15 is a circuit diagram of an exemplary three-tap tapped-delay line filter according to one exemplary embodiment of the present invention.



FIG. 16 is a graph that illustrates how the effective Q-factor varies with the initial iterations of the adaptive filter for an electrical multilevel signal according to one exemplary embodiment of the present invention.



FIG. 17 is a graph that illustrates how the effective Q-factor varies with the initial iterations of the adaptive filter for a multilevel signal going through 100 km of fiber according to one exemplary embodiment of the present invention.



FIG. 18 is a graph of an Eye-diagram for an unfiltered multilevel electrical drive signal that can be used as an input to the present invention.



FIG. 19 is a graph of an Eye-diagram for a filtered multilevel electrical drive signal according to one exemplary embodiment of the present invention.



FIG. 20 is a graph of an Eye-diagram for an unfiltered multilevel optical signal that can be used as an input to the present invention.



FIG. 21 is a graph of an Eye-diagram for a filtered multilevel optical signal according to one exemplary embodiment of the present invention.



FIG. 22 is a graph illustrating how the effective Q-factor varies with the initial iterations of the adaptive filter for a multilevel signal with inter-symbol interference according to one exemplary embodiment of the present invention.



FIG. 23 is a graph of an Eye-diagram for an unfiltered multilevel optical signal that can be used as an input to the present invention.



FIG. 24 is a graph of an Eye-diagram for a filtered multilevel optical signal according to one exemplary embodiment of the present invention.



FIG. 25 illustrates a signal conditioning filter (SCF) fabricated in GaAs as an integrated circuit that contains a variable gain input amplifier and a transit detector circuit for clock recovery according to one exemplary embodiment of the present invention.



FIG. 26 is a graph that illustrates a 5 Gbps unfiltered binary signal after transmission over 34″ of copper trace in a backplane that can used as input to the present invention.



FIG. 27 is a graph that illustrates the signal of FIG. 26 after equalization with the signal conditioning filter according to one exemplary embodiment of the present invention.



FIG. 28 is a graph that illustrates an unfiltered 10 Gbps (4-level 5 G sym/s) signal after transmission over 150 m of multimode fiber that can be used as input to the present invention.



FIG. 29 is a graph that illustrates the multilevel signal of FIG. 28 after equalization with the signal conditioning filter according to one exemplary embodiment of the present invention.





DETAILED DESCRIPTION OF THE EXEMPLARY EMBODIMENTS

The present invention can address the problems of equalization and noise filtering in order to improve signal fidelity for decoding. Specifically, a received digital signal can be filtered in a manner to optimize the signal fidelity even in the presence of both large magnitudes of ISI and noise. Furthermore, the method and system of the present invention can be adaptive in the sense that filter coefficients can be continuously updated to reflect any time-varying changes in the channel behavior.


Filter Structure


Referring now to FIG. 1A, an equalization and filtering system 102 can comprise a variable gain amplifier 105, a signal conditioning filter (SCF) 100, a decoder or clock and data recovery (CDR) unit 120, and a signal integrity unit (SIU) 125. The CDR 120, SIU 125, and VGA 105 can form parts of a signal detection and fidelity characterization circuit 130 as will be discussed below with respect to FIG. 2. The exemplary signal conditioning filter (SCF) 100 can comprise two filters, a short-time filter 110 and a long-time filter 115 that are cascaded together.


According to one exemplary embodiment, each filter 110, 115 of the signal conditioning filter 100 can comprise a tapped-delay line or finite impulse response (FIR) filter with electrically controllable gain coefficients. Filtering is separated into these two stages, where the short-time filter 110 can comprise the first stage and the long-time filter can comprise the second stage. Each stage is designed to address a particular type of distortion using a relatively small number of taps.


As its name implies, the short-time filter 110 can be designed to mitigate degradations such as ringing, noise, and timing jitter that can occur on a relatively small time scale. Meanwhile, the long-time filter 115 is designed to remove signal artifacts (such as ISI) that can occur on a larger time scale.


Referring now to FIG. 1B, the signal integrity unit 125 can comprise a low pass filter (LPF) 132 and an analog-to-digital converter 135, a controller or processor 140, and a plurality of digital-to-analog converters (DACs) 145. After low-pass filtering by the LPF 132, a DC component of the sampled signal remains and is termed the event monitor voltage and is an analog probability estimate for the controlled reference voltage exceeding the received signal y(t) where controlled reference voltage is generated by the digital-to-analog converters 145.


As mentioned above, the output of the LPF 132 can be fed to the analog-to-digital converter (ADC) 135. The ADC 135 may be characterized as a low-speed high-resolution ADC that measures the averaged event-detector output representing the cumulative distribution function (CDF) value. Specifically, the reference voltage is swept over a range of voltage levels while the ADC 135 samples the voltage from the filter 132 to produce an estimate of the CDF. The SIU 125 can set the reference voltage via the DAC 145 to a fixed value and then measures the averaged event detection output. The SIU 125 can then set the reference voltage to a different fixed value and measures another point of the CDF. This process is completed until the CDF curve is formed.


The ADC 135 feeds its output to a microcontroller 140. Microcontroller 140 can process the cumulative distribution function (CDF) to determine threshold voltage values for signal decoding, receiver gain for the variable gain amplifier 105, and filter coefficients for the SCF 100. The microcontroller 140 is responsible for feeding the filter coefficients to the SCF for equalizing and filtering the received signal. Further details of the signal integrity unit 125 are discussed in the commonly owned U.S. Non-provisional application Ser. No. 10/108,598 entitled, “METHOD AND SYSTEM FOR DECODING MULTILEVEL SIGNALS,” filed on Mar. 28, 2002 in the name of Vincent Hietala et al., the entire contents of which are hereby incorporated by reference.


Referring now to FIG. 2, a first input to the signal conditioning filter (SCF) 100 can comprise a signal y(t) that can include an unfiltered received signal while the output to the SCF 100 can comprise a filtered signal z(t). The filtered signal z(t) can be propagated into the signal detection and fidelity characterization circuit 130. As mentioned above, the signal detection and fidelity characterization circuit 130 can comprise a CDR 120 and SIU 125.


A first output of the signal detection and fidelity characterization circuit 130 can comprise the decoded data from the filtered signal z(t). A second output of the signal detection and fidelity characterization circuit 130 can comprise a control signal q(t) that forms a second input to the SCF 100.


Referring now to FIG. 3, as noted above with respect to FIG. 1, the SCF 100 can comprise a short-time filter 110 that receives the signal y(t) discussed above with respect to FIG. 2. The short-time filter 110 manipulates the signal y(t) according to a first function gs(t). The output from the short-time filter 110 can comprise a first filtered signal y-prime′(t) that is fed as the input to the long-time filter 115.


The long-time filter 115 manipulates the signal y-prime′(t) according to a second function gL(t). The output from the long-time filter 115 can comprise a second filtered signal or z(t) as mentioned above with respect to FIG. 2 that is fed as the input to the CDR 120 or SIU 125 (not shown in FIG. 2).


Referring now to FIG. 4, the exemplary short-time filter 110 can comprise a tapped-delay line filter with amplifiers 405 and N delay elements 410 (each with delay δ) and N+1 amplifiers with gain coefficients αn for n=0, . . . ,N. The delay δ can be chosen to be small (relative to the symbol period T0 of the signal) to permit the short-time filter 110 to perform at least one of three functions: (1) compensate for signal distortions (such as ringing) that can occur within a single symbol period; (2) effectively integrate over less than a symbol period to integrate out and reduce the noise; and (3) adjust the amount of signal smoothing to be large enough to reduce the effects of signal distortion and noise but to be short enough to be robust relative to the timing jitter in the system.


The short-time filter 110 can support a frequency resolution of 1/Nδ. It is assumed that the delay δ is sufficiently small so that there is no aliasing in the short-time filter 110. Specifically, the short-time filter 110 has a frequency response that is periodic in frequency with period 1/δ. Any signal (or noise) energy at frequencies higher than f=1/(2δ) will distort the filtered signal as they overlap into adjacent spectral periods. Because of this distortion, it is recommended that the signal be pre-filtered with a passive analog low-pass filter (not shown) prior to the short-time filter 110. This pre-filtering may not needed if any of the receiver components already sufficiently bandlimits the signal, as is often the case with circuit hardware and the high speeds considered.


The output of the short-time filter 110 can be written as

y′(t)=α0y(t)+α1y(t−δ)+ . . . +αNy(t−Nδ)  (1)

or equivalently as

y′(t)=[α01+ . . . +αN]y(t)−α1[y(t)−y(t−δ)]− . . . −αn[y(t)−y(t−Nδ)]  (2)

where the latter form explicitly conveys how the short-time filter 110 operates on the difference between the current sample and a sample from the past, i.e. each term can provide a first-order correction for the signal fluctuation within a symbol period. Furthermore, the coefficient on y(t) in Eq. (2) provides the DC gain of the signal, i.e. the gain on the signal when the signal is already flat within a symbol period, and hence, all the differential terms are zero. As a reference, unity DC gain can be chosen by setting α0 to

α0=1−α1− . . . −αN  (3)

or by alternatively normalizing the filter coefficients to sum to one.


Referring now to FIG. 5, the exemplary long-time filter 115 can comprise a tapped-delay line filter with M delay elements 410′ (each with a delay equal to the symbol period T0) and M+1 amplifiers 405 with gain coefficients αm for m=0, . . ,M. The purpose of this long-time filter 115 is to remove ISI which occurs between symbols. Because the short-time filter 110 is capable of smoothing the signal over a significant portion of the symbol period, the long-time filter 115 need not worry about aliasing associated with the signal frequencies higher than the sampling rate 1/T0. If the short-time filter 115 were not present, then an anti-aliasing filter with a low-cutoff frequency may be needed.


Similar to Eqs. (1) and (2), the output of the long-time filter 115 can be written as

z(t)=α0y′(t)+α1y′(t−T0)+ . . . +αMy′(t−MT0)  (4)

or equivalently,

z(t)=[α01+ . . . +αM]y′(t)−α1[y′(t)−y′(t−Δ)]− . . . −αM[y′(t)−y′(t−MΔ)]  (5)

where again, a unity DC gain can be arbitrarily chosen by setting

α0=1−α1− . . . −αN  (6)

or by scaling the coefficients to sum to one.


Those skilled in the art can extend the exemplary filters in FIGS. 4 and 5 to account for subsequent as well as preceding signal samples. For example, additional L taps could be added to the short-time filter 110 of FIG. 4 to change Eq. (2) to yield

y′(t)=[α0+ . . . +αN+L]y(t)−α1[y(t)−y(tδ)]− . . . −αN+L[y(t)−y(t−(N+L)δ)].

The signal sample y(t−Lδ) can be interpreted as the sample to be decoded, i.e. where the decoding has been delayed by process by time Lδ. Because, the signal points y(t) through y(t−(L−1)δ precede y(t−Lδ), the ISI associated from these symbols can be removed. Thus, the short-time filter 110 can now remove ISI originating from both preceding and succeeding signal samples. The long-time filter 115 may be similarly modified. This extension can be applied to both the short and long-time filters 110, 115 in practice as it can help improve equalization.


Filtering in the Transmitter


Referring now to FIG. 6, although described for use in a receiver, the SCF 110 may also be used in a transmitter 600 to maximize the fidelity of the transmit signal before channel noise is introduced which limits signal restoration in a corresponding receiver (not shown). Specifically, SCF 100 and SIU 125 modules may be placed in the transmitter 600 immediately before transmission circuitry as illustrated in FIG. 6 where these modules can be used to minimize the effects of ringing, ISI, circuit impedance mismatches, and noise introduced by the transmitter.


Removing these distortions prior to transmission is advantageous because the noise introduced by the channel limits the degree to which the transmitter 600 distortions can be compensated by the receiver's SCF 100. Additionally, if a supervisory communications link is available between the transmitter 600 and receiver (not shown), then the fidelity signal q(t) may be fed from the receiver (not shown) to the transmitter 600 over this link so that the SCF 100 in the transmitter not only compensates for transmitter distortions, but also pre-compensates for link distortions. This pre-compensation would be advantageous because it prevents the noise introduced by the link from limiting the degree to which the channel distortions can be compensated.


Filter Realization


The exemplary short- and long-time filters 110, 115 forming the SCF 100 can be implemented using an integrated tapped-delay line filter structure 100A with the basic structure illustrated in FIG. 7. This exemplary filter structure 100A is functionally identical to the conceptual tapped-delay line filter diagrams of FIGS. 3 and 4 if τ is associated with δ for FIG. 4 and T0 for FIG. 5.


The filter structure 100A shown in FIG. 7 offers efficient “re-use” of the time delays for the various signal paths. This can be important since time delays are generally physically quite large and thus difficult to integrate. Therefore, it is desirable to make optimal use of all delay elements.


To understand this efficient “re-use” of the delays, shown in FIG. 8 is the signal path for the third filter tap with gain coefficient g3. For this tap, by inspection, the total signal delay will be six times (×)τ/2 or 3τ. Similarly, by observation, the delay of the signal for each tap gi is i (times)×τ. Thus, the output signal y(t) can be represented as follows:











y


(
t
)


=




k
=
0

4








g
k



x


(

t
-

k





τ


)





,




(
7
)








which is identical to the form of Equations (1) and (4) discussed above.


A block diagram of an exemplary variable gain tap amplifier 900 for a tap filter is illustrated in FIG. 9. In this exemplary embodiment, the gain constant GC is multiplied with the signal Vin to allow for both positive and negative gain coefficients. The input signal Vin is amplified/buffered, multiplied by the gain coefficient GC, and then output as a current source lout. The input amplifier/buffer 902 is designed to have high input impedance as to not disturb the input delay line. The output of the amplifier 900 is also designed to be high impedance as to similarly not disturb the output delay line. In practice, a significant parasitic capacitance remains at both the input and output of the amplifier 900, but as will be seen below, these parasitics can be absorbed into the delay lines.


For one exemplary embodiment of the present invention, a delay element can comprise a simple LC (inductor-capacitor) delay line. However, those skilled in art will recognize that other delay elements can be used and are not beyond the scope and spirit of the present invention.


A representative LC delay line 1800 is illustrated in FIG. 10. This delay line 1000 forms a high order low-pass filter function with a relatively constant delay over the passband. Those skilled-in-the-art will recognize that a variety of filter design methodologies could be employed to construct higher performance delay structures, but the one shown in FIG. 10 was used for simplicity. It should also be realized that the lumped elements could be realized by distributed elements or in fact a variety of different delay elements could be similarly used.


For the simple delay structure shown, assuming constant L and Cl, the delay, τ is approximately:

τ=NLC√{square root over (LCl)}  (8)

in which NLC is the number of LC pairs and the filter's termination resistance, R0 is:










R
o




L

C
l







(
9
)








The end of each delay element needs to be terminated with R0 in parallel with a capacitor of approximately Cl/2 for proper operation.


Referring now to FIG. 11, an exemplary embodiment of a three tap tapped-delay line filter 100C using the. variable gain tap amplifier of FIG. 9 and the lumped LC delay element shown in FIG. 10 is illustrated. Several important design aspects of this filter structure 100C can now be explained.


First, it is important to realize that the cascade of delay elements 1102 and circuitry on the left-hand side of the circuit 100C is designed to form a well controlled delay line. This will be referred to as the “input delay line” 1102. Similarly, on the right-hand side of the circuit 100C comprising the two delay elements and associated circuitry in this simple exemplary embodiment, will be referred to as the “output delay line” 1104.


Both the input and output delay lines 1102, 1104 are designed to have minimal signal attenuation and reflections in order to maintain good signal fidelity. As such, as already mentioned, the inputs of the amplifiers g were designed with high impedance and the remaining input capacitance is “absorbed” into the loading capacitance of the input delay line 1102.


This absorbed capacitance can be seen in FIG. 11 by the reduced values of loading capacitance (Cl–Cin). Additionally, the input and the output of the input delay lines 1102, 1104 are carefully terminated in the characteristic resistance (R0) of the delay elements. Similarly, the output delay line 1104 absorbs the output parasitic capacitance of the amplifiers and is terminated with the appropriate resistance (R0). The output of each amplifier g launches a signal in both directions in the output delay line 1104 and thus it can be appreciated why proper termination can be critical for proper filter operation.



FIGS. 12 through 15 illustrate an exemplary circuit embodiment of two tap tapped-delay line filters. The designs are fully differential, but one skilled-in-the-art will realize that the concepts discussed above are equally applicable to differential or single-ended designs. The particular exemplary embodiments illustrated in these figures are for integration in a GaAs HBT process. One skilled-in-the-art will realize that other device technologies could similarly be applied.


Specifically, FIG. 12 illustrates the circuit diagram of an exemplary variable gain tap amplifier 1200. The input is first buffered by high input-impedance emitter follower amplifiers X16 and X17. The output of the emitter follower amplifiers drives a lower pair of a standard Gilbert cell multiplier circuit (also called a Gilbert cell mixer and an XOR gate) comprising X14, X13, X9, X10, X11 and X12. The bases of the upper cross connected differential pairs are held at the desired DC gain constant. Since this circuit is an effect 4-quadrant multiplier, the gain coefficient can be negative or positive.


The R8, R10 and R9, R11 resistor divider networks scale the input drive voltage so that desired coefficient control range is achieved (approx. +/−1 V in this case). The output of the Gilbert cell multiplier circuit is terminated by the output delay line. The Gilbert cell multiplier will usually see a real load resistance of R0/2. The output will have a significant output capacitance due the collector capacitances of X9, X10, X11, and X12, but as discussed above, this capacitance can be absorbed into the output delay line.


Referring now to FIG. 13, the design for an exemplary 5-tap τ=T0/5 short-time tapped-delay line filter 100D that is based on artificial transmission lines is illustrated. For this filter 100D, it was found that only one LC pair was required for each tap (2nd order low-pass filter). Each delay element can provide 37 (pico-seconds) ps of delay (½ of ⅕ period at 2.7 Gbps). The inductors used were integrated spiral inductors with a nominal inductance of 2.7 nH. The actual loading capacitor values were initially selected as indicated above, but optimized for the best frequency response in the actual design. A series resistance R1304 was added to the loading capacitors C1304 to lower the phase peaking at the stopband edge. An additional shunt resistance R1306 was added to help counteract the effect of the inductor loss Inductor loss makes the delay lines characteristic resistance complex. The addition of an appropriate shunt resistance can cancel this effect and make the characteristic impedance real at a target frequency. The input and output of the filter 100D are buffered by amplifiers 1302 to isolate the circuit from external influences.


For the long-time filter 115 (3-tap τ=T0), a six stage LC filter was required to obtain the necessary delay of 185 ps. Referring now to FIG. 14, this figure illustrates an exemplary circuit of an individual long delay element 1400. Four of these long delay elements 1400 were used in the exemplary filter embodiment 100E illustrated in FIG. 15. The exemplary filter embodiment 100E of FIG. 15 can be referred to as a 3-tap long-time tapped-delay line filter.


Coefficient Adaptation Algorithm


The gains of the filter tap amplifiers g are adjusted to maximize a signal fidelity measure q(t) (provided by the SIU 125 for example). The general idea is to slightly perturb the coefficients and observe the effect on q(t). Doing this allows a set of coefficient values to be determined that locally maximizes the signal fidelity. The approach continually perturbs the coefficients to survey the signal fidelity's dependence on the coefficients and tune the SCF 100 to the optimal values in an adaptive fashion. The method is presented for the case of the short-time filter, but the approach is equally applicable to the long-time filter. Alternatively, the cascade of the two filters can be viewed as a single filter whose coefficients are adapted by the following method as will be discussed below.


The intuition in the preceding paragraph can be made precise by restating it as the following optimization problem










α
*

=



arg





max

α



{

q


(
t
)


}






(
10
)








where α denotes the vector of adjustable filter coefficients and q(t) quantifies the fidelity of the signal (such as a measure of the signal's Q-factor as produced by the SIU[4]). Eq. (10) is solved via an empirical minimization of q(t). Towards this end, a coordinate descent algorithm can be used to find the local maximum by searching over each coordinate while the others are held fixed (i.e. perturbing one of the filter coefficients α0, α1, . . . , αN at a time). One skilled in the art will realize that other numerical optimization techniques (such as gradient, Newton, and conjugate methods) may also be used to solve Eq. (10).


In some contexts, simply maximizing the signal fidelity may not be sufficient to provide good SCF performance. In particular, there is the possibility of a null-space of solutions. For example, consider the task of short-time equalization when there is no ringing and noise on the received signal to compensate. An intuitive solution would be to have α0=1 and αn=0 for all other n, i.e. perform no filtering. However, an equally valid solution would be, α0=1, α1=A, α2=−A, and αn=0 for all other n where A can be any value (including arbitrarily large values). Other convoluted (but still valid) sets of coefficients can also be obtained. The drawbacks of such non-intuitive solutions are

    • 1. They obscure the identifiability of the coefficients which are actually helping to improve signal fidelity. For instance, in the above example, α1 and α2 effectively cancel each other and do nothing to reduce ringing or noise.
    • 2. They reduce the robustness of the system to changes in the channel characteristics. In particular, if the channel characteristics change such that the null-space “moves” (e.g. a little ringing is introduced), then α1 and α2 will no longer cancel each other and a very erratic signal will result until the coefficients are relearned to remove such artifacts.


Motivated by such problems, there may be the desire to guide the values of the filter coefficients αn, in addition to maximizing the signal fidelity. To achieve such a result, a regularization penalty can be imposed in the objective function. For example, solving the following optimization problem could be chosen in place of Eq. (10):










α
*

=



arg





max

α



{



q


(
t
)


2

-

γ





a
-
β



2
2



}






(
11
)








where γ and β are regularization parameters. The parameter β is a nominal value for α. Specifically, β is the value one would expect α* to be in the absence of any channel distortion. While β represents the nominal value of α*, γ represents confidence in β and determines how strongly α* is driven towards β. Note that if no biasing is desired, then γ should be set to zero, and Eq. (11) reduces to Eq. (10). Thus, Eq. (10) can be seen as a specific case of Eq. (11). One skilled in the art will realize that a variety of penalty functions can be used in place of the 2-norm in Eq. (11).


As previously stated, the long-time filter coefficients can similarly be adapted according to Eq. (11), i.e. it can be chosen that










a
*

=



arg





max

a



{



q


(
t
)


2

-

γ





a
-
b



2
2



}






(
12
)








where b is the nominal value for the long-time filter coefficients. The nominal situation again corresponds to when the channel introduces no signal distortion. For example, if one generally believes the channel introduces no ISI, then b should generally resemble a Euclidean basis vector, i.e. a vector with a single 1 and the rest zeros. That is, the nominal long-time filter should not do much filtering.


Automatic Gain Control


Thus far, the special case of no DC amplification on the filtered multilevel signal has been considered. A non-unity gain could be selected. And if a variable gain amplifier (VGA) module 105 is to lead or follow the SCF 100, then the control of the VGA module 105 may be incorporated into the SCF's 100 control. In particular, if the desired gain AVGA can be obtained as an external signal (perhaps determined in the SIU 125, then the SCF 100 can control the gain by simply scaling all of the coefficients αn (or an) by AVGA. This is simply a mathematical operation that can be performed after the calculation of filter coefficients in Eq. (11) or (12). Alternately, the gain control of the VGA module 105 can be adjusted as needed by the SIU.


Simulation Results


To demonstrate results of the proposed filtering method, the inventors completed a MATLAB simulation as applied to real data of a 4-PAM signal in an optical communications system.


First, a system dominated by short-time effects, i.e. ringing and noise, is examined. Specifically, an electrical drive signal and a received signal after 100 km of fiber is considered. The progression of the fidelity measure as the filter adaptation algorithm iterates is shown in FIGS. 16 (for the electrical drive signal) and 17 (for the received optical signal). Specifically, the graph 1600 in FIG. 16 conveys the value of the signal fidelity measure as the filter coefficients are being adjusted. From the plot 1602, it can be seen that the fidelity of the signal is improved as the coefficients are adjusted. The numerical improvement conveyed by plot 1602 can be further appreciated by considering the eye-diagrams in FIGS. 18 and 19. FIG. 18 shows the eye diagram for the signal before any filtering, i.e. at iteration 0 in graph 1600. FIG. 19 shows the eye-diagram of the signal after filtering on iteration 7 in graph 1600. Clearly, the amount of ringing on the signal has been reduced through the use of filtering providing a better quality signal.



FIG. 17 is analogous to FIG. 16, except that FIG. 17 is for a photodetected optical signal after 100 km of optical fiber. Specifically, graph 1700 in FIG. 17 shows the progression of the fidelity measure as the filter coefficients are adjusted in each iteration for this optical system. FIGS. 20 and 21 are analogous to FIGS. 18 and 19. In particular, FIG. 20 shows an eye-diagram of the photodetected optical signal before any filtering. Clearly, the signal is of poor quality as exhibited by the nearly closed eye-openings 2002C. FIG. 21, however, shows very wide eye-openings 2002D that are produced after filtering the signal with the described invention.


In addition to the short-time distortion noise dominated data sets in FIGS. 16 through 22, another data set in which the signal is predominantly degraded by ISI is examined. Again, the context is an optical system with 100 km of fiber, but contrary to the system used for FIGS. 8, 11, and 12, a different photodetector is used which is less vulnerable to noise, thus leaving ISI as the dominant source of signal degradation. The evolution of the signal fidelity is shown in FIG. 22 from which we see a significant improvement in signal quality (almost doubling the fidelity measure). The eye-diagrams associated with the SCF are shown in FIGS. 23 (without filtering) and 24 (with filtering). The increase in the eye-opening from before filtering 2302A to after filtering 2302B clearly conveys the improvement in signal quality afforded by the SCF.


Laboratory Results


An exemplary IC implements the filter embodiment discussed above, as illustrated by the circuit 2500 of FIG. 25. The circuit 2500 was fabricated in a GaAs HBT process. The short-time filter 2505 comprises five coefficient amplifiers 2510 and eight delay elements 2515 to realize the 5-tap tapped-delay line filter illustrated in FIG. 22. As previously described, a pair of τ/2 delay elements 2515 are used to produce the desired delay of τ (τ/2 from the input side and τ/2 from the output side).


Meanwhile, the long-time filter 2520 comprises three coefficient amplifiers 2510 and four delay elements 2525 to realize the 3-tap long-time filter illustrated in FIG. 24. Coefficient amplifiers 2510 are Gilbert cell multipliers with identical topologies, although specific circuit parameters may vary as each multiplier is optimized according to the surrounding circuit.


The improved output provided by the SCF circuit 2500 of FIG. 25 is illustrated by FIGS. 26 and 27. FIG. 26 illustrates a received signal from a backplane communications system transmitting a binary signal at a data rate of 5 Gbps over a 34″ copper trace. Specifically, FIG. 26 illustrates the condition of the received electrical binary signal in the form of an eye-diagram 2600. Clearly, no reliable data can be recovered from this received signal as there is no eye-opening.


Meanwhile, referring now to FIG. 27, this figure shows an eye-diagram 2700 for the same received signal illustrated in FIG. 26 but being processed by the SCF 100 and its corresponding control method. The eye-openings 2705 are now clearly visible affording reliable communications which was unachievable without equalization.


Referring now to FIGS. 28 and 29, these figures demonstrate the improvement provided by the SCF 100 in an optical communications system. The system channel now includes optical components. Specifically, the electrical data signal is converted to an optical signal with a VCSEL (vertical cavity surface emitting laser), transmitted over 150 m of multimode fiber (MMF), and converted back to an electrical signal at the receiver with a photodetector.



FIG. 28 illustrates an eye diagram 2800 where the condition of the received electrical signal when a 4-level 5Gsym/s (yielding a 10 Gbps data rate) is transmitted. Again, there are no visible eye-openings in the received signal and thus data cannot be reliably recovered.


Meanwhile, in FIG. 29, an eye-diagram 2900 for the same received signal is illustrated but after filtering with the SCF 100 of one exemplary embodiment of the present invention. The four signal levels are now apparent from the eye-openings 2905 which means that data can be recovered from this received and filtered signal.


Therefore, the present invention provides an adaptive filtering approach that combines channel equalization and noise filtering. The method and system of the present invention can easily support high speed digital communications which combines channel equalization and noise filtering in a single framework. The method and system of the present invention can account for the effects that equalization can have on noise filtering, and vice-versa. Furthermore, the method and system are adaptive in nature and have a practical means of implementation for high-speed data communications systems.


It should be understood that the foregoing relates only to illustrate the embodiments of the present invention, and that numerous changes may be made therein without departing from the scope and spirit of the invention as defined by the following claims.

Claims
  • 1. A system for processing digital signals comprising symbols propagated according to a period, the system comprising: a signal conditioning filter comprising a first stage for mitigating degradations of a digital signal that occur according to a first time scale, the first stage comprising a linear tapped-delay line filter tuned to the first time scale, the first time scale comprising a fraction of the period at which the symbols are propagated, and a second stage for removing signal distortions that occur according to a second time scale, the second stage comprising a linear tapped-delay line filter tuned to the second time scale, the second time scale being different than the first time scale and comprising a magnitude at least equal to the period at which the symbols are propagated; anda signal integrity unit for controlling the signal conditioning filter by maximizing fidelity of the digital signals.
  • 2. The system of claim 1, wherein the signal conditioning filter comprises a coefficient amplifier, the coefficient amplifier comprising a Gilbert cell multiplier.
  • 3. The system of claim 1, wherein each tapped delay-line filter comprises LC circuits.
  • 4. The system of claim 1, wherein delays are distributed across both input and output branches of each tapped delay-line filter.
  • 5. The system of claim 1, wherein parasitic capacitances from one of an input and output of each tapped-delay line filter are absorbed into an LC design circuit and are used to implement the delay.
  • 6. The system of claim 1, wherein the digital signals comprise binary signals.
  • 7. The system of claim 1, wherein the digital signals comprise multilevel signals.
  • 8. The system of claim 1, wherein the first and second stages comprise various signal pats of different lengths where time delays produced by the signal paths are re-used.
  • 9. A system for processing digital signals comprising: a first filter stage comprising a first linear tapped-delay line filter tuned to a first time constant, the first time constant comprising a value that is less than a symbol period, for compensating for signal distortions tat occur within a single symbol period and for integrating over less than a symbol period in order to substantially reduce at least one of ringing, jitter, and noise; anda second filter stage comprising a second linear tapped-delay line filter tuned to a second time constant, the first time constant being smaller than the second time constant and the second time constant comprising value at least equal to a symbol period, the second filter stage for removing inter-symbol interference (ISI).
  • 10. The system of claim 9, wherein each filter comprises a coefficient amplifier, the coefficient amplifier comprising a Gilbert cell multiplier.
  • 11. The system of claim 9, wherein each tapped delay-line filter comprises LC circuits.
  • 12. The system of claim 9, wherein delays are distributed across both input and output branches of each tapped delay-line filter.
  • 13. The system of claim 9, wherein parasitic capacitances from one of an input and output of each tapped-delay line filter are absorbed into the LC design circuit and are used to implement the delay.
  • 14. The system of claim 9, wherein the digital signals comprise binary signals.
  • 15. The system of claim 9, wherein the digital signals comprise multilevel signals.
  • 16. The system of claim 9, wherein the first and second filtering stages form part of a unit for receiving digital signals.
  • 17. The system of claim 9, wherein the first and second filtering stages form part of a unit for transmitting digital signals.
  • 18. A system for processing digital signals comprising symbols propagated according to a period, the system comprising: a cascade of two linear filters, where each filter comprises a series of variable gain amplifiers connected by delay elements, each delay element for a respective filter having a same delay value, each linear filter equalizing a particular frequency band of a multilevel signal;the delay elements in the first filter being tuned to a fraction of the symbol period at which the symbols are propagated for compensating for signal distortions that occur within a single symbol period and for integrating over less than a symbol period in order to substantially reduce at least one of ringing, jitter, and noise;the delay elements in the second filter being tuned to a magnitude at least equal to the symbol period at which symbols are propagated for mitigating degradations that occur according to the period.
  • 19. The system of claim 18, wherein each variable gain amplifier comprises a Gilbert Cell multiplier.
  • 20. The system of claim 18, wherein the delay elements of the first and second filters comprise delay lines.
  • 21. The system of claim 18, wherein the delay elements of the first and second filters comprise delay lines that include LC circuits.
  • 22. The system of claim 18, further comprising a signal integrity unit for controlling each filter.
  • 23. The system of claim 22, wherein the signal integrity unit measures fidelity of a filtered signal, each filter further comprising a variable gain coefficient amplifier, and gains of each variable gain coefficient amplifier are controlled to maximize fidelity measured byte signal integrity unit.
CROSS REFERENCE TO RELATED APPLICATIONS

The present application claims priority under 35 U.S.C. § 119(e) to U.S. Provisional Application Ser. No. 60/396,065 entitled, “ADAPTIVE NOISE FILTERING AND EQUALIZATION FOR OPTIMAL HIGH SPEED SIGNAL DECODING,” filed on Jul. 15, 2002 in the name of Andrew Joo Kim et al. The entire contents of which are hereby incorporated by reference. This application is also related to U.S. Non-provisional application Ser. No. 10/108,598 entitled, “METHOD AND SYSTEM FOR DECODING MULTILEVEL SIGNALS,” filed on Mar. 28, 2002 in the name of Vincent Hietala et al., the entire contents of which are hereby incorporated by reference.

US Referenced Citations (237)
Number Name Date Kind
2632058 Gray Mar 1953 A
3445771 Clapham et al. May 1969 A
3571725 Kaneko et al. Mar 1971 A
3599122 Leuthold Aug 1971 A
3714437 Kinsel Jan 1973 A
3806915 Higgins et al. Apr 1974 A
3977795 Buschmann Aug 1976 A
4287756 Gallagher Sep 1981 A
4288872 Tamburelli Sep 1981 A
4349914 Evans Sep 1982 A
4363127 Evans et al. Dec 1982 A
4386339 Henry et al. May 1983 A
4387461 Evans Jun 1983 A
4393499 Evans Jul 1983 A
4464771 Sorensen Aug 1984 A
4470126 Haque Sep 1984 A
4475227 Belfield Oct 1984 A
4479266 Eumurian et al. Oct 1984 A
4521883 Roché Jun 1985 A
4580263 Watanabe et al. Apr 1986 A
4584720 Garrett Apr 1986 A
4618941 Linder et al. Oct 1986 A
4646173 Kammeyer et al. Feb 1987 A
4651026 Serfaty et al. Mar 1987 A
4751497 Torii Jun 1988 A
4830493 Giebeler May 1989 A
4847521 Huignard et al. Jul 1989 A
4864590 Arnon et al. Sep 1989 A
4873700 Wong Oct 1989 A
4912726 Iwamatsu et al. Mar 1990 A
4942593 Whiteside et al. Jul 1990 A
4953041 Huber Aug 1990 A
4959535 Garrett Sep 1990 A
4978957 Hotta et al. Dec 1990 A
5007106 Kahn et al. Apr 1991 A
5008957 Klyono Apr 1991 A
5012475 Campbell Apr 1991 A
5067126 Moore Nov 1991 A
5072221 Schmidt Dec 1991 A
5111065 Roberge May 1992 A
5113278 Degura et al. May 1992 A
5115450 Arcuri May 1992 A
5121411 Fluharty Jun 1992 A
5128790 Heidemann et al. Jul 1992 A
5132639 Blauvelt et al. Jul 1992 A
5151698 Pophillat Sep 1992 A
5181034 Takakura et al. Jan 1993 A
5181136 Kavehrad et al. Jan 1993 A
5184131 Ikeda Feb 1993 A
5208833 Erhart et al. May 1993 A
5222103 Gross Jun 1993 A
5223834 Wang et al. Jun 1993 A
5225798 Hunsinger et al. Jul 1993 A
5237590 Kazawa et al. Aug 1993 A
5243613 Gysel et al. Sep 1993 A
5252930 Blauvelt Oct 1993 A
5282072 Nazarathy et al. Jan 1994 A
5283679 Wedding Feb 1994 A
5291031 MacDonald et al. Mar 1994 A
5293406 Suzuki Mar 1994 A
5300930 Burger et al. Apr 1994 A
5321543 Huber Jun 1994 A
5321710 Cornish et al. Jun 1994 A
5327279 Farina et al. Jul 1994 A
5343322 Pirio et al. Aug 1994 A
5351148 Maeda et al. Sep 1994 A
5355240 Prigent et al. Oct 1994 A
5361156 Pidgeon Nov 1994 A
5371625 Wedding et al. Dec 1994 A
5373384 Hebert Dec 1994 A
5376786 MacDonald Dec 1994 A
5382955 Knierim Jan 1995 A
5387887 Zimmerman et al. Feb 1995 A
5408485 Ries Apr 1995 A
5413047 Evans et al. May 1995 A
5416628 Betti et al. May 1995 A
5418637 Kuo May 1995 A
5424680 Nazarathy et al. Jun 1995 A
5428643 Razzell Jun 1995 A
5428831 Monzello et al. Jun 1995 A
5436752 Wedding Jul 1995 A
5436756 Knox et al. Jul 1995 A
5444864 Smith Aug 1995 A
5450044 Hulick Sep 1995 A
5481389 Pidgeon et al. Jan 1996 A
5481568 Yada Jan 1996 A
5483552 Shimazaki et al. Jan 1996 A
5504633 Van Den Enden Apr 1996 A
5510919 Wedding Apr 1996 A
5515196 Kitajima et al. May 1996 A
5528710 Burton et al. Jun 1996 A
5548253 Durrant Aug 1996 A
5574743 van der Poel et al. Nov 1996 A
5589786 Bella et al. Dec 1996 A
5606734 Bahu Feb 1997 A
5612653 Dodds et al. Mar 1997 A
5617135 Noda et al. Apr 1997 A
5621764 Ushirokawa et al. Apr 1997 A
5625360 Garrity et al. Apr 1997 A
5625722 Froberg et al. Apr 1997 A
5644325 King et al. Jul 1997 A
5648987 Yang et al. Jul 1997 A
5670871 Man et al. Sep 1997 A
5675600 Yamamoto Oct 1997 A
5678198 Lemson Oct 1997 A
5689356 Rainal Nov 1997 A
5691978 Kenworthy Nov 1997 A
5692011 Nobakht et al. Nov 1997 A
5699022 Tovar Dec 1997 A
5706008 Huntley, Jr. et al. Jan 1998 A
5721315 Evans et al. Feb 1998 A
5723176 Keyworth et al. Mar 1998 A
5751726 Kim May 1998 A
5754681 Watanabe et al. May 1998 A
5757763 Green et al. May 1998 A
5761243 Russell et al. Jun 1998 A
5764542 Gaudette et al. Jun 1998 A
5774505 Baugh Jun 1998 A
5783630 Evans et al. Jul 1998 A
5784032 Johnston et al. Jul 1998 A
5790595 Benthin et al. Aug 1998 A
5798854 Blauvelt et al. Aug 1998 A
5801657 Fowler et al. Sep 1998 A
5802089 Link Sep 1998 A
5812578 Schemmann et al. Sep 1998 A
5825211 Smith et al. Oct 1998 A
5825257 Klymyshyn et al. Oct 1998 A
5825825 Altmann et al. Oct 1998 A
5828329 Burns Oct 1998 A
5839105 Ostendorf et al. Nov 1998 A
5841841 Dodds et al. Nov 1998 A
5844436 Altmann Dec 1998 A
5848139 Grover Dec 1998 A
5850409 Link Dec 1998 A
5850505 Grover et al. Dec 1998 A
5852389 Kumar et al. Dec 1998 A
5859862 Hikasa et al. Jan 1999 A
5861966 Ortel Jan 1999 A
5872468 Dyke Feb 1999 A
5878390 Kawai et al. Mar 1999 A
5880870 Sieben et al. Mar 1999 A
5883910 Link Mar 1999 A
5887022 Lee et al. Mar 1999 A
5889759 McGibney Mar 1999 A
5896392 Ono et al. Apr 1999 A
5912749 Harstead et al. Jun 1999 A
5920600 Yamaoka et al. Jul 1999 A
5923226 Kakura et al. Jul 1999 A
5942576 Evans et al. Aug 1999 A
5943380 Marchesani et al. Aug 1999 A
5943457 Hayward et al. Aug 1999 A
5949926 Davies Sep 1999 A
5959032 Evans et al. Sep 1999 A
5959750 Eskildsen et al. Sep 1999 A
5965667 Evans et al. Oct 1999 A
5968198 Hassan et al. Oct 1999 A
5978417 Baker et al. Nov 1999 A
5983178 Naito et al. Nov 1999 A
5985999 Dominguez et al. Nov 1999 A
5999300 Davies et al. Dec 1999 A
6002274 Smith et al. Dec 1999 A
6002717 Gaudet Dec 1999 A
6009424 Lepage et al. Dec 1999 A
6011952 Dankberg et al. Jan 2000 A
6021110 McGibney Feb 2000 A
6028658 Hamada et al. Feb 2000 A
6031048 Evans et al. Feb 2000 A
6031866 Oler et al. Feb 2000 A
6031874 Chennakeshu et al. Feb 2000 A
6034996 Herzberg Mar 2000 A
6035080 Henry et al. Mar 2000 A
6041299 Schuster et al. Mar 2000 A
6052420 Yeap et al. Apr 2000 A
6072364 Jeckeln et al. Jun 2000 A
6072615 Mamyshev Jun 2000 A
6078627 Crayford Jun 2000 A
6084931 Powell, II et al. Jul 2000 A
6091782 Harano Jul 2000 A
6093496 Dominguez et al. Jul 2000 A
6093773 Evans et al. Jul 2000 A
6108474 Eggleton et al. Aug 2000 A
6111477 Klymyshyn et al. Aug 2000 A
6118563 Boskovic et al. Sep 2000 A
6118567 Alameh et al. Sep 2000 A
6127480 Dominguez et al. Oct 2000 A
6140416 Evans et al. Oct 2000 A
6140858 Dumont Oct 2000 A
6140972 Johnston et al. Oct 2000 A
6141127 Boivin et al. Oct 2000 A
6141387 Zhang Oct 2000 A
6148428 Welch et al. Nov 2000 A
6151150 Kikuchi Nov 2000 A
6154301 Harvey Nov 2000 A
6163638 Eggleton et al. Dec 2000 A
6169764 Babanezhad Jan 2001 B1
6169912 Zuckerman Jan 2001 B1
6181454 Nagahori et al. Jan 2001 B1
6191719 Bult et al. Feb 2001 B1
6201916 Eggleton et al. Mar 2001 B1
6208792 Hwang et al. Mar 2001 B1
6212654 Lou et al. Apr 2001 B1
6214914 Evans et al. Apr 2001 B1
6219633 Lepage Apr 2001 B1
6226112 Denk et al. May 2001 B1
6236963 Naito et al. May 2001 B1
6259836 Dodds Jul 2001 B1
6259847 Lenz et al. Jul 2001 B1
6268816 Bult et al. Jul 2001 B1
6271944 Schemmann et al. Aug 2001 B1
6281824 Masuda Aug 2001 B1
6288668 Tsukamoto et al. Sep 2001 B1
6289055 Knotz Sep 2001 B1
6289151 Kazarinov et al. Sep 2001 B1
6298459 Tsukamoto Oct 2001 B1
6304199 Fang et al. Oct 2001 B1
6311045 Domokos Oct 2001 B1
6313713 Ho et al. Nov 2001 B1
6317469 Herbert Nov 2001 B1
6341023 Puc Jan 2002 B1
6356374 Farhan Mar 2002 B1
6388786 Ono et al. May 2002 B1
6411117 Hatamian Jun 2002 B1
6421155 Yano Jul 2002 B1
6473131 Neugebauer et al. Oct 2002 B1
6501792 Webster Dec 2002 B1
6539204 Marsh et al. Mar 2003 B1
6665348 Feher Dec 2003 B1
6665500 Snawerdt Dec 2003 B1
6751587 Thyssen et al. Jun 2004 B1
6816101 Hietala et al. Nov 2004 B1
20020196508 Wei et al. Dec 2002 A1
20030002121 Miyamoto et al. Jan 2003 A1
20030008628 Lindell et al. Jan 2003 A1
20030058976 Ohta et al. Mar 2003 A1
20030067990 Bryant Apr 2003 A1
20040213354 Jones et al. Oct 2004 A1
20040218756 Tang et al. Nov 2004 A1
Foreign Referenced Citations (21)
Number Date Country
0 527 966 Sep 1994 EP
0 584 865 Mar 2000 EP
0 223 369 Apr 1990 GB
2 306 066 Apr 1997 GB
62082659 Oct 1988 JP
1990000063162 Nov 1991 JP
04187738 Jul 1992 JP
08079186 Mar 1996 JP
WO 9945683 Sep 1999 WO
WO 0141346 Jun 2001 WO
WO 02067521 Aug 2002 WO
WO 2002082694 Oct 2002 WO
WO 02091600 Nov 2002 WO
WO 2003071731 Aug 2003 WO
WO 03077423 Sep 2003 WO
WO 03092237 Nov 2003 WO
WO 2004008782 Jan 2004 WO
WO 2004045078 May 2004 WO
WO 2004088857 Oct 2004 WO
WO 2005018134 Feb 2005 WO
WO 2005050896 Jun 2005 WO
Related Publications (1)
Number Date Country
20040012433 A1 Jan 2004 US
Provisional Applications (1)
Number Date Country
60396065 Jul 2002 US