Aspects of the present application relate to electronic signal processing. More specifically, to methods and systems for hypotheses generation based on multidimensional slicing.
Traditional reduced complexity sequence estimation or trellis algorithms are based on best path search. Survivor paths are selected based on extended path metric calculation for every path candidate. The total number of extended path metrics is the product of the number of survivors and the symbol constellation size (Alphabet consists of M symbols), meaning that every survivor is duplicated M times in order to find the most probable successors (e.g., M-algorithm). Such process exhibits huge amount of complexity in case of large Alphabet size. In the presence of low SNR (close to the cutoff rate), it is required to increase the number of survivors beyond M to assure near ML (Maximum Likelihood) performance.
Methods and systems are provided for hypotheses generation based on multidimensional slicing, substantially as illustrated by and/or described in connection with at least one of the figures, as set forth more completely in the claims.
Expression (1) represents the recursive log-likelihood score (metric) function for ML detection:
J(ŝ[n])=J(ŝ[n−1])−|y[n]−â[n]T·{tilde over (h)}|2, (1)
where y[n] represents the sample of the received signal at time instant n. The received signal may be a partial response (PR) signal or may be a signal that was transmitted with near-zero inter-symbol interference (ISI) (e.g., via an root raised cosine (RRC) pulse-shaping filter) but which has ISI as a result of channel effects (e.g., multipath). {tilde over (h)} represents the N{tilde over (h)} PR filter taps coefficients, ŝ[n]=[â[n−N
BM[n](m,k)=−|y[n]−â[n](m,k)·{tilde over (h)}|2, m=1, 2, . . . , M; and k=1, 2, . . . , A. (2)
The successor scores are updated with the branch metric:
J[n](m,k)=J[n−1](m,k)+BM[n](m,k), m=1, 2, . . . , M; and k=1, 2, . . . , A. (3)
The survivors are taken to be the M successors (out of the M·A total successors) with the highest log-likelihood score J[n](m,k). The M-algorithm may be subject to severe performance degradation around the threshold SNR (cutoff rate) as a result of Correct Path Loss (CPL) events. A CPL event occurs when the successor corresponding to the actual transmitted sequence attains a relatively-low successor score compared to other successors, and is consequently not selected as one of the M survivors for the next iteration. Such an event results in an inevitable error event which could have been avoided in a full-blown ML decoding. It is possible to reduce the CPL event probability by increasing the number of survivors retained for each iteration, but this entails larger complexity, in particular when operating close to the cutoff rate. The CPL event also depends on the magnitude of the first tap coefficient of the composite filter that provides the estimated composite response {tilde over (h)}. The magnitude of the first coefficient plays a significant role in the selection of the survivors. This coefficient multiplies the most-recent symbol of the successors and determines the branch metrics of the successors. Thus, in the conventional M-algorithm, the A branch metrics of the A successors generated from the mth survivor differ based only on their respective most-recent symbols. When the first tap coefficient magnitude is relatively small, the information in the new branch is relatively meager, and thus is not reliable, especially for relatively low SNR values. Another drawback of the conventional M-algorithm is that it may be considered cumbersome and not cost effective to perform a search over the entire alphabet size (i.e., to generate, and calculate branch metrics for, all A successors for each of the M survivors), since, given the survivor state and the incoming sample, certain ones of the A possible symbol values are more likely than others.
Aspects of this disclosure, provide for performance (e.g., measured in symbol error rate, bit error rate, and/or the like) that meets or exceeds the conventional M-algorithm with less cost and/or complexity. In this regard, aspects of this disclosure provide a sequence estimation technique that extracts information from the Euclidean space to calculate and compare branch metrics using only the most-likely hypotheses. This approach enables to improve performance and reduce complexity. For each of the M successors generated from the mth survivor, a branch vector hypothesis may be inserted at one or more symbol locations (the “branch locations”), at least one of which may be associated with a relatively large (perhaps largest) one of the coefficients p, where p is the vector (of length Np) of filter tap coefficients of a filter corresponding the estimated composite response {tilde over (h)}. In this manner, the CPL probability may be significantly reduced relative to the conventional M-algorithm in which the branch locations consist only of the most-recent symbol location, which is associated with the first of the coefficients p (which is typically relatively-small for spectral mask compliance).
Shown in the transmitter 100 are a forward error correction (FEC) encoder 102, a modulator 104, and an analog/RF front-end 106. The encoder 102, modulator 104, and front-end 106 may, for example, be integrated on one or more semiconductor dies (e.g., 102 and 104 may be part of a baseband processor integrated circuit (IC) and the front-end 106 may comprise discrete components and/or a second IC). In various example implementations, the transmitter 100 may be similar to, or the same as, the transmitters described in one or more of the above-incorporated patents and applications (e.g., transmitter 120 of U.S. patent application Ser. No. 13/922,329), but may differ in operation or configuration from such transmitters where necessary to implement aspects of this disclosure.
In an example implementation, the transmitter 100 may use a linear modulation scheme such as Pulse Amplitude Modulation (PAM) or Quadrature Amplitude Modulation (QAM) usually with a zero-ISI (Inter-symbol Interference) pulse shaping filter. That is, the pulse shaping filter (e.g., in front end 106) may take on a zero value at any integer multiple of the symbol period, t=nT, where n in an integer and T is the symbol period (except for n=0). Zero-ISI signals are generated by filters that obey the so-called Nyquist's Second Criterion, for example, a raised-cosine filter.
In another example implementation, the transmitter 100 may use a linear modulation scheme along with partial response pulse shaping that introduces correlation between successive symbols. Such a filter does not introduce nulls at time instants which are integer multiples of the symbol period. The transmit signal generated by such a filter intentionally has a substantial amount of ISI. The ISI is therefore a controlled ISI. A partial response signal is just one example of a type of signal for which there is correlation among symbols of the signal (referred to herein as “inter-symbol-correlated (ISC) signals”). Accordingly, in still other example implementations, the transmitter 100 may transmit other ISC signals such as, for example, signals generated via matrix multiplication (e.g., lattice coding), signals generated via decimation as in multi-carrier applications such as in OFDM systems, and signals corrupted by some nonlinear distortion such as phase noise and amplifier compression.
Shown in the receiver 108 are an analog/RF front-end 110, a sequence estimation circuit 112, and an FEC decoding circuit 114. The analog/RF front-end 110, a sequence estimation circuit 112, and an FEC decoding circuit 114 may, for example, be integrated on one or more semiconductor dies (e.g., 112 and 114 may be part of a baseband processor integrated circuit (IC) and the front-end 110 may comprise discrete components and/or a second IC). In various example implementations, the receiver 108 may be similar to, or the same as, the receiver described in one or more of the above-incorporated patents and applications (e.g., receiver 130 of U.S. patent application Ser. No. 13/922,329), but may differ in operation or configuration from such receivers where necessary to implement aspects of this disclosure.
First considering the case where the AWGN is negligible, any modulated sample, y[n], of signal 117 received by receiver 108 can be represented by an inner product between a sequence of symbols aT transmitted by transmitter 100, and the coefficients p of the composite filter that models the composite response of the front-end 106, the channel 116, and the front-end 110. This inner product can be expressed as y=aT·p and may be considered as a point of an Np-dimensional lattice (a “partial lattice”). This inner product may be represented by two contributions: a1T·p1 and a2T·p2 (i.e., aT·p=a1T·p1+a2T·p2). Thus, a2T·p2=y−a1T·p1, may be considered as a partial, N2-dimensional lattice slicing problem, where N2 stands for the length of p2, a2 consists of N2 symbols, and N2<Np. Assuming that a1T·p1 is known, it is possible to generate a hypothesis for the branch vector a2 (a branch vector hypothesis is denoted â2) based on the partial lattice point Dx=y−a1T·p1 using a multidimensional slicing. The slicing may be performed by the sequence estimation circuit 112 using a look-up table populated based on the known response p2 (i.e., â2=LUT{Dx}). The look-up table represents the partial lattice generated by the response p2 and, in an example implementation for an ideal channel, there may be a one-to-one mapping between partial lattice points Dx and branch vector hypotheses â2.
Now considering the case where the AWGN is not negligible, each sample of the received signal 117 is given by r=y+η, where η represents the AWGN, and may correspond to a residual signal value Dr=r−a1T·p1. As a result of the noise, the residual signal value Dr may be off the partial lattice (i.e., not coincide with any of the partial lattice points Dx). Consequently, the hypotheses â2(1) corresponding to the ML solution based on a single received sample r is the partial lattice point Dx that is closest to residual signal value Dr. Additional branch vector hypotheses (denoted â2(k), k=2, 3, . . . Q) corresponding to the Q−1 partial lattice points Dx that are next-closest to the residual signal value Dr may also be determined from the slicing. That is, rather than a one-to-one mapping, any particular residual signal value Dr may be mapped to Q hypotheses of the branch vector a2 (denoted â2(k), k=1, 2, 3, . . . Q) per survivor. The hypotheses can be used as an alternative to the exhaustive search performed by the M-algorithm. The hypotheses have depth of N2 rather than depth of 1 as in the conventional M-algorithm. In an example implementation, the branch vector hypotheses may be inserted into the successors at the branch locations which have indexes of [N2+1, N2+2, . . . 1, n]. Consequently, the hypotheses for a current iteration may overwrite symbols of one or more hypotheses from one or more previous iterations. Thus, the successors of the mth survivor may comprise: (1) survivor symbols in locations which have indexes of [Np+1, Np+2, . . . N2], and (2) branch symbols in locations which have indexes of [N2+1, N2+2, . . . 1, n]. By generating successors in this way it is possible to recover from a CPL event.
The generation of branch vector hypotheses may be considered as a multidimensional slicing. This slicing is based on the response p2 that may be selected to incorporate the tap coefficients with relatively-high (perhaps the highest) magnitude in order to improve the reliability of the slicing compared to the search carried out by the M-algorithm. In an example implementation, the algorithm may be formulated as follows: Assuming that at time instant n−1, the mth survivor is â[n−1](m)=[â[n−N
â[n](m,k)=[â[n−N
The N2 branch symbols of the kth successor (i.e., the kth hypothesis) for the mth survivor may then be represented as:
â2[n](m,k)[â[n−N
Assuming that â1[n](m,k)=â1[n](m)[â[n−N
the 2nd hypothesis for the mth survivor as:
and, in general, the kth hypothesis for the mth survivor as:
where {tilde over (h)}=[{tilde over (h)}1 {tilde over (h)}2] represents the decomposition of the composite response to the partial lattice structure, and argmin â2{F(â2)} is the value of â2 that minimizes the expression F(â2). The tap coefficients of {tilde over (h)} are represented in this disclosure as {tilde over (h)}x, for 1≦x≦Np. For relatively small values of N2 (e.g., less than 10), the set of hypotheses â2[n](m,k), k=1, 2, . . . , Q may be extracted with low complexity by a look-up table built according to the partial response ĥ2. This table uses as its input the residual signal value r[n]−â1[n](m)·{tilde over (h)}1. For reference, when N2=N{tilde over (h)}, and Q=AN{tilde over (h)}−1, then the proposed method coincides with the full state space ML search.
As discussed above, in typical reduced complexity sequence estimation algorithms, a single symbol branch vector (e.g., inserted at index 0 of the successors) is used for branch metric calculation. This typically results in branch metrics that are unreliable due to the low amplitude of the tap coefficient associated with the single branch location. Using a two symbol branch vector (e.g., inserted at indexes 1 and 0 of the successors) is much more reliable because of the higher magnitude of the tap coefficient associated with the second branch location (e.g., the tap coefficient associated with index 1). The reliability, however, comes at the price of much more complexity. For example in the case of M-algorithm, calculating branch metrics for two branch symbols will require M3 branch metric calculations (M2 branch metrics for each of M survivors) instead of M2 branch metric calculations (M branch metrics for each of the M survivors) for the single branch symbol case. Thus, complexity of the Look-Up Table (LUT) grows exponentially with increase in number of branch symbols. Conversely, complexity of the LUT increases only linearly with increase in number of branch symbols when using the partial (multidimensional) lattice slicing approach described herein.
The flowchart in
In block 202, a new sample, r[n], of a modulated signal is received.
In block 204, an inverse nonlinear function is operated on the received sample r[n]. The inverse nonlinear function may be an approximation of the inverse of a nonlinearity experienced by the modulated signal through the transmitter 100, channel 116, and/or receiver front end 110. The inverse nonlinear function may be adapted dynamically at the receiver for variations caused by, for example, a change of environmental conditions (e.g., temperature, power supply, etc.) and power level that may affect the nonlinear distortion level.
In block 206, the signal resulting from the operation of the inverse nonlinear function is filtered using an LPF (Low-Pass Filter) to reject out-of-band components that may be generated by the inverse nonlinear operation. In case that the nonlinear distortion is small comparing to the received signal-to-noise ratio (SNR), the blocks 204 and 206 may be bypassed.
In block 208, the residual signal value is calculated per survivor according to the term LPF{fNL−1(r[n])}−â1[n](m)·{tilde over (h)}1, where â1[n](m) represents N−N2 symbols of the mth survivor at time instant n, and LPF{fNL−1(r[n])} represents the filtered inverse nonlinear signal.
In block 210, the resulting M residual signal values are used to generate Q hypotheses per survivor. Each hypothesis may consist of N2 branch symbols that may override N2−1 branch symbols of the survivor of the previous iteration. The hypothesis generation may be realized by a LUT or by arithmetic circuit.
In block 212, for each one of the M·Q successors, a branch metric is computed and accumulated with that successor's path score from the previous iteration to arrive at an updated path score.
In block 214, the M paths having the highest M updated path scores are selected to be the new survivors for the next iteration.
In block 216, the survivors are shifted one symbol. That is, the symbol at index Np shifts out of the tail of the survivor, the symbol at index Np+1 shifts to index Np, the symbol at index Np+2 shifts to index Np+1, and so on down to the symbol at index 0 shifting to index 1 such that the location at index 0 is ready for the next sample. The process then returns to block 202 in which that next sample is received.
The partial lattice corresponds to a subset of the taps of the PR filter, and thus they take part in the overall PR filter characteristics of the modulation such as spectrum response, susceptibility for nonlinear distortion, Symbol-Error-Rate (SER), Bit-Error-Rate (BER) and the resulting most probable error patterns (e.g., as described, for example, in the above-incorporated U.S. patent application Ser. Nos. 13/754,998 and 13/755,026). Therefore, the construction of the partial lattice may be combined with the design of the PR filter while the partial lattice considerations affects the ratios among the first N2 taps of the PR filter. Considering the design of the partial lattice taps apart of the full PR filter, the construction of the partial lattice can be determined according to the following objectives:
The above objectives may be in conflict and a constrained optimization is needed. As an example,
We now consider a system with nonlinear distortion that affects the modulated signal. In that case, the signal can no longer be represented by a linear decomposition, such as is described above. Accordingly, an inverse estimation of the nonlinear model may be used on the received signal prior to the partial slicing. The nonlinear inverse will attempt to cancel the nonlinear distortion and will enable correct linear decomposition. The nonlinear inverse operation may enhance AWGN that distorts the received signal which may increase the distance of the correct hypothesis from the residual signal that may result in a CPL event caused by the limited coverage of the limited number of hypotheses. The partial slicing may tolerate that by increasing the number of hypotheses used per survivor.
The inverse nonlinear operation may result in spectral regrowth that produces out-of-band spectral components which are not present in the received signal due to filtering in the receiver (e.g., bandpass filter (BPF) at the RF font-end, analog lowpass filter (LPF) at the I-Q baseband, digital filters in the demodulator). Therefore a LPF may be used following the nonlinear inverse operation to improve the effectiveness of the partial slicing and hypotheses generation.
Assuming use of a suboptimal partial lattice such as depicted in
As was described above, iteration at time instant n provides Q hypotheses per survivor. In an example implementation, each of the hypotheses consists of N2 symbols that may override the first N2−1 symbols of the survivors from the iteration at time instant n−1. The symbol index N2 of each the survivors from the iteration at time instant n−1 is not affected by the hypotheses generated at time instant n. Clearly, the first N2−1 survived symbols values may vary by the next iterations thus the values of these symbols are used only for branch metric and score calculations that are used to select the new survivors. As the survivor number is limited (e.g., M survivors) it is desirable to increase the diversity among them on the symbol located at index N2−1. Taking the hypotheses using the pure Euclidean distance may result with hypotheses that differ in the first (most recent) N2−1 symbols but share the same symbols at location having index N2−1. This lack of diversity among the hypotheses on the symbol located at index N2−1 increases the probability of CPL and an error event. Therefore, in an example implementation, the hypotheses may be selected using a diversity-distance criteria, that is, a minimum Euclidean distance that is constrained for increased (or even maximum) diversity rather than pure Euclidean distance. In an example implementation, the diversity-distance criteria may be selected to ensure that, for any Q hypotheses (per survivor), there will be Q different symbols located at index N2−1 in case that Q≦M, or M different symbols in case that Q>M. The diversity-distance criteria will increase the occupied volume of the hypotheses that can be used for improved performance as well as to reduce complexity by using fewer hypotheses to occupy similar volume as the Euclidean distance criteria. The diversity-distance criterion may be implemented using a LUT similar to the pure Euclidean distance criteria. The input to the LUT may be a quantized version of the residual signal. The quantization resolution may be smaller than the occupied volume of the hypotheses (i.e., it may be a relatively coarse quantization).
In an example implementation, an additional, or alternative, criteria may be used to ensure that, for any Q hypotheses (per survivor), at least a threshold number of the symbols located at index N2−1 will be equal to the symbol at index N2−2 in the hypothesis of the previous iteration. That is, when generating a hypothesis for a symbol at index N2−1, some preference or bias may be given to the hypothesis that was generated for that symbol in the previous iteration when the symbol was at index N2. The strength of such a bias may depend on the amplitudes of the tap coefficients corresponding to index N2−2. That is, if the tap coefficient corresponding to index N2−2 is very low (and thus very unreliable), then perhaps little or no preference may be given to the hypothesis from the previous iteration, but if the tap coefficient corresponding to index N2−2 is relatively high (and thus relatively reliable), then more preference may be given to the hypothesis from the previous iteration.
The sequence estimation uses the paths score that are updated by the branch metric as described with reference to equations 1, 2, 3. The path score uses the first Np symbols per path. Therefore, the branch metrics and scores may be regressively recomputed N2−1 times due to the overriding of the first N2−1 symbols of the previous branch vector hypotheses.
In case of high SNR and/or low nonlinear distortion, the variance of the residual signal around the lattice point will be small and a relatively low number of hypotheses may be sufficient to protect against CPL. However, in low SNR and/or high nonlinear distortion conditions, the variance may increase and a relatively-higher number of hypotheses may be needed to sufficiently protect against CPL. Accordingly, the number of hypotheses may be adapted according to the SNR and/or amount of nonlinearity to reduce complexity and power consumption when possible.
In operation, the symbol constellation 730 used by the transmitter 100 for generating the signal 115 (received by the receiver 108 as signal 117) is convolved with {tilde over (h)}2 to generate the partial lattice. For the example of 32-QAM, the convolution may result in the partial lattice of
The survivors 701 are shifted by circuit 706 resulting in M vectors 707 which are a first input to the circuit 708. In the example implementation depicted, the symbols in the first two locations (indexes N2−1 and 0) are “don't cares” after the shift, since they are not needed for calculation of the residual signal values. For practical purposes, a symbol from the previous hypothesis may remain in location with index N2−1 and a zero may be inserted into location with index 0 until they are overridden by a newly generated hypothesis.
The current sample of the received signal is operated on by the circuits 726 and 728 resulting in signal 729 which is a second input to the circuit 708. The circuit 708 calculates M residual signal values Dr[n]1 . . . Dr[n]M (reference designator 709) based on the vectors 707 and the signal 729. Each of the residual signal values is then sliced by circuit 710 to generate M*Q hypotheses 711. In an example implementation, the circuit 710 comprises a memory storing a look-up table indexed by values of Dx. For each of the residual signal values, the circuit 710 may determine the Q values of Dx that are closest to residual signal value (e.g., based on a diversity-distance criteria), and retrieve the corresponding Q branch vector hypotheses. The hypotheses are output to circuit 712 which duplicates each of the vectors 707 Q−1 times and then inserts the Q hypothesis into the most-recent N2 symbols of the vector, resulting in M*Q successors (called out as 714). Circuit 722 then calculates a branch metric (e.g., according to expression (2) above) for each of the M*Q successors. The branch metrics are output to circuit 724 which updates the path metrics (e.g., according to expression (3)) above. The M successors having the best path metrics are selected to be the survivors for the next iteration (i.e., for estimating same r[n+1]). The survivor having the best path score may thus represent the best estimate of the transmitted symbol sequence corresponding to the received sample r[n]. One or more symbols of the best survivor may accordingly be output by the sequence estimation circuit 112 (e.g., output to FEC decoder 114) as an estimate of a transmitted symbol. For example, at time n, the symbol at index N2−1 of the best survivor may be output as the estimate of the symbol transmitted by transmitter 100 at time n−N2−1−Δ, where Δ is the delay, in symbol times, between a symbol being transmitted by transmitter 100 and the corresponding signal being sampled by receiver 108. The output may be a hard decision or a soft-decision (e.g., an LLR). The soft-decision may be weighted based on the location of the residual signal value within the partial lattice (e.g., LLR may indicate increased confidence of a particular symbol value when the residual signal is closer to a boundary of the partial lattice).
In accordance with an example implementation of this disclosure, a sample of PR (Partial Response) signal can be represented by a lattice point that belongs to a full dimension lattice that consists of MN
In accordance with an example implementation of this disclosure, a sequence estimation circuit (e.g., 112) of a receiver (e.g., 108) may receive a sample of an inter-symbol correlated (ISC) signal (e.g., r[n]
A quantity of branch vectors hypotheses in the one or more branch vector hypotheses may be determined (e.g., in real-time) per sample of the received ISC signal such that different quantities of branch vectors hypotheses may be generated for consecutive samples of the received ISC signal. For example, a larger quantity may be used for a sample corresponding to a residual signal value that is relatively close (e.g., within a determined Euclidean distance DE) to the center of the multidimensional partial lattice and a smaller quantity may be used for a sample corresponding to a residual signal value that is relatively far (e.g., not within the determined Euclidean distance DE) from the center of the multidimensional partial lattice. As another example, a larger quantity may be used for samples having a relatively low signal-to-noise ratio (e.g., below a determined threshold SNR ThSNR) and a smaller quantity may be used for samples having a relatively high signal-to-noise ratio (e.g., above the determined threshold SNR ThSNR). As another example, a larger quantity may be used for samples experiencing relatively large amounts of nonlinear distortion (e.g., above a determined threshold distortion ThNL) and a smaller quantity may be used for samples experiencing relatively small amounts of nonlinear distortion (e.g., below the determined threshold distortion ThNL).
The ISC signal may comprise a single-carrier or multiple orthogonal frequency division multiplexed (OFDM) carriers. The transmitted symbol sequence may have been transmitted in accordance with a regulatory spectral mask (e.g., set forth by the FCC or ETSI). The one or more of the branch vector hypotheses may be used to extend a survivor vector, wherein, as part of the extension of the survivor vector, one or more symbols of the survivor vector corresponding to a previous branch vector hypothesis (e.g., symbol at N2−1) is overridden by one or more of the plurality of symbols of the one or more of the branch vector.
The present method and/or system may be realized in hardware, software, or a combination of hardware and software. The present methods and/or systems may be realized in a centralized fashion in at least one computing system, or in a distributed fashion where different elements are spread across several interconnected computing systems. Any kind of computing system or other apparatus adapted for carrying out the methods described herein is suited. A typical combination of hardware and software may be a general-purpose computing system with a program or other code that, when being loaded and executed, controls the computing system such that it carries out the methods described herein. Another typical implementation may comprise an application specific integrated circuit or chip. Some implementations may comprise a non-transitory machine-readable (e.g., computer readable) medium (e.g., FLASH drive, optical disk, magnetic storage disk, or the like) having stored thereon one or more lines of code executable by a machine, thereby causing the machine to perform processes as described herein.
While the present method and/or system has been described with reference to certain implementations, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the present method and/or system. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from its scope. Therefore, it is intended that the present method and/or system not be limited to the particular implementations disclosed, but that the present method and/or system will include all implementations falling within the scope of the appended claims.
As utilized herein the terms “circuits” and “circuitry” refer to physical electronic components (i.e. hardware) and any software and/or firmware (“code”) which may configure the hardware, be executed by the hardware, and or otherwise be associated with the hardware. As used herein, for example, a particular processor and memory may comprise a first “circuit” when executing a first one or more lines of code and may comprise a second “circuit” when executing a second one or more lines of code. As utilized herein, “and/or” means any one or more of the items in the list joined by “and/or”. As an example, “x and/or y” means any element of the three-element set {(x), (y), (x, y)}. As another example, “x, y, and/or z” means any element of the seven-element set {(x), (y), (z), (x, y), (x, z), (y, z), (x, y, z)}. As utilized herein, the terms “e.g.,” and “for example” set off lists of one or more non-limiting examples, instances, or illustrations. As utilized herein, circuitry is “operable” to perform a function whenever the circuitry comprises the necessary hardware and code (if any is necessary) to perform the function, regardless of whether performance of the function is disabled, or not enabled, by some user-configurable setting.
This application claims priority to the following application(s), each of which is hereby incorporated herein by reference: U.S. Provisional Patent Application Ser. No. 61/726,099 titled “Modulation Scheme Based on Partial Response” and filed on Nov. 14, 2012;U.S. Provisional Patent Application Ser. No. 61/729,774 titled “Modulation Scheme Based on Partial Response” and filed on Nov. 26, 2012;U.S. Provisional Patent Application Ser. No. 61/747,132 titled “Modulation Scheme Based on Partial Response” and filed on Dec. 28, 2012;U.S. Provisional Patent Application Ser. No. 61/768,532 titled “High Spectral Efficiency over Non-Linear, AWGN Channels” and filed on Feb. 24, 2013; andU.S. Provisional Patent Application Ser. No. 61/807,813 titled “High Spectral Efficiency over Non-Linear, AWGN Channels” and filed on Apr. 3, 2013. The entirety of each of the following applications is hereby incorporated herein by reference: U.S. Pat. No. 8,582,637 titled “Low-Complexity, Highly-Spectrally-Efficient Communications;”U.S. patent application Ser. No. 13/754,998, titled “Design and Optimization of Partial Response Pulse Shape Filter,” and filed on Jan. 31, 2013;U.S. Pat. No. 8,675,769 titled “Constellation Map Optimization For Highly Spectrally Efficient Communications;”U.S. Pat. No. 8,571,131 titled “Dynamic Filter Adjustment for Highly-Spectrally-Efficient Communications;”U.S. Pat. No. 8,559,494, titled “Timing Synchronization for Reception of Highly-Spectrally-Efficient Communications;”U.S. Pat. No. 8,559,496, titled “Signal Reception Using Non-Linearity Compensated, Partial Response Feedback;”U.S. Pat. No. 8,599,914, titled “Feed Forward Equalization for Highly-Spectrally-Efficient Communications;”U.S. Pat. No. 8,665,941, titled “Decision Feedback Equalizer for Highly-Spectrally-Efficient Communications;”U.S. patent application Ser. No. 13/755,025, titled “Decision Feedback Equalizer with Multiple Cores for Highly-Spectrally-Efficient Communications,” and filed on Jan. 31, 2013;U.S. Pat. No. 8,559,498 titled “Decision Feedback Equalizer Utilizing Symbol Error Rate Biased Adaptation Function for Highly-Spectrally-Efficient Communications;”U.S. Pat. No. 8,548,097 titled “Coarse Phase Estimation for Highly-Spectrally-Efficient Communications;”U.S. Pat. No. 8,565,363 “Fine Phase Estimation for Highly Spectrally Efficient Communications;”U.S. patent application Ser. No. 13/755,972, titled “Multi-Mode Transmitter for Highly-Spectrally-Efficient Communications,” and filed on Jan. 31, 2013;U.S. Pat. No. 8,605,832, titled “Joint Sequence Estimation of Symbol and Phase with High Tolerance of Nonlinearity;”U.S. Pat. No. 8,553,821 titled “Adaptive Non-Linear Model for Highly-Spectrally-Efficient Communications;”U.S. patent application Ser. No. 13/755,052, titled “Pilot Symbol Aided Sequence Estimation for Highly-Spectrally-Efficient Communications,” and filed on Jan. 31, 2013;U.S. Pat. No. 8,666,000 titled “Reduced State Sequence Estimation with Soft Decision Outputs;”U.S. Pat. No. 8,571,146 titled “Method and System for Corrupt Symbol Handling for Providing High Reliability Sequences;”U.S. Pat. No. 8,566,687 titled “Method and System for Forward Error Correction Decoding with Parity Check for Use in Low Complexity Highly-Spectrally Efficient Communications;”U.S. patent application Ser. No. 13/755,061, titled “Method and System for Quality of Service (QoS) Awareness in a Single-Channel Communication System,” and filed on Jan. 31, 2013;U.S. Pat. No. 8,665,992 titled “Pilot Symbol Generation for Highly-Spectrally Efficient Communications;”U.S. Pat. No. 8,548,072 titled “Timing Pilot Generation for Highly-Spectrally Efficient Communications;”U.S. patent application Ser. No. 13/756,010, titled “Multi-Mode Receiver for Highly-Spectrally-Efficient Communications,” and filed on Jan. 31, 2013;U.S. Pat. No. 8,572,458 titled “Forward Error Correction with Parity Check Encoding for Use in Low Complexity Highly-Spectrally Efficient Communications;”U.S. Pat. No. 8,526,523 titled “Highly-Spectrally-Efficient Receiver;”U.S. patent application Ser. No. 13/921,665 titled “Highly-Spectrally-Efficient Transmission Using Orthogonal Frequency Division Multiplexing,” and filed on Jun. 19, 2013;U.S. patent application Ser. No. 13/921,710 titled “Highly-Spectrally-Efficient Reception Using Orthogonal Frequency Division Multiplexing,” and filed on Jun. 19, 2013;U.S. patent application Ser. No. 13/921,749 titled “Multi-Mode OFDM Transmitter for Highly-Spectrally-Efficient Communications,” and filed on Jun. 19, 2013; andU.S. Pat. No. 8,681,889 titled “Multi-Mode OFDM Receiver for Highly-Spectrally-Efficient Communications.”
Number | Name | Date | Kind |
---|---|---|---|
4109101 | Mitani | Aug 1978 | A |
4797925 | Lin | Jan 1989 | A |
5249200 | Chen et al. | Sep 1993 | A |
5283813 | Shalvi et al. | Feb 1994 | A |
5394439 | Hemmati | Feb 1995 | A |
5432821 | Polydoros et al. | Jul 1995 | A |
5459762 | Wang et al. | Oct 1995 | A |
5602507 | Suzuki | Feb 1997 | A |
5757855 | Strolle et al. | May 1998 | A |
5784415 | Chevillat et al. | Jul 1998 | A |
5818653 | Park et al. | Oct 1998 | A |
5886748 | Lee | Mar 1999 | A |
5889823 | Agazzi et al. | Mar 1999 | A |
5915213 | Iwatsuki et al. | Jun 1999 | A |
5930309 | Knutson et al. | Jul 1999 | A |
6032284 | Bliss | Feb 2000 | A |
6167079 | Kinnunen et al. | Dec 2000 | A |
6233290 | Raphaeli | May 2001 | B1 |
6233709 | Zhang et al. | May 2001 | B1 |
6272173 | Hatamian | Aug 2001 | B1 |
6335954 | Bottomley et al. | Jan 2002 | B1 |
6516437 | Van Stralen et al. | Feb 2003 | B1 |
6535549 | Scott et al. | Mar 2003 | B1 |
6697441 | Bottomley et al. | Feb 2004 | B1 |
6785342 | Isaksen et al. | Aug 2004 | B1 |
6871208 | Guo et al. | Mar 2005 | B1 |
6968021 | White et al. | Nov 2005 | B1 |
6985709 | Perets | Jan 2006 | B2 |
7158324 | Stein et al. | Jan 2007 | B2 |
7190288 | Robinson et al. | Mar 2007 | B2 |
7205798 | Agarwal et al. | Apr 2007 | B1 |
7206363 | Hegde et al. | Apr 2007 | B2 |
7467338 | Saul | Dec 2008 | B2 |
7702991 | Haratsch | Apr 2010 | B2 |
7830854 | Sarkar et al. | Nov 2010 | B1 |
7974230 | Talley et al. | Jul 2011 | B1 |
8005170 | Lee et al. | Aug 2011 | B2 |
8059737 | Yang | Nov 2011 | B2 |
8175186 | Wiss et al. | May 2012 | B1 |
8248975 | Fujita et al. | Aug 2012 | B2 |
8351536 | Mazet et al. | Jan 2013 | B2 |
8422589 | Von Elbwart et al. | Apr 2013 | B2 |
8548089 | Agazzi et al. | Oct 2013 | B2 |
20020016938 | Starr | Feb 2002 | A1 |
20020123318 | Lagarrigue | Sep 2002 | A1 |
20020150065 | Ponnekanti | Oct 2002 | A1 |
20020150184 | Hafeez et al. | Oct 2002 | A1 |
20030016741 | Sasson et al. | Jan 2003 | A1 |
20030210352 | Fitzsimmons et al. | Nov 2003 | A1 |
20040120409 | Yasotharan et al. | Jun 2004 | A1 |
20040170228 | Vadde | Sep 2004 | A1 |
20040227570 | Jackson et al. | Nov 2004 | A1 |
20050047517 | Georgios et al. | Mar 2005 | A1 |
20050135472 | Higashino | Jun 2005 | A1 |
20050220218 | Jensen et al. | Oct 2005 | A1 |
20050265470 | Kishigami et al. | Dec 2005 | A1 |
20050276317 | Jeong et al. | Dec 2005 | A1 |
20060067396 | Christensen | Mar 2006 | A1 |
20060109780 | Fechtel | May 2006 | A1 |
20060171489 | Ghosh et al. | Aug 2006 | A1 |
20060203943 | Scheim et al. | Sep 2006 | A1 |
20060245765 | Elahmadi et al. | Nov 2006 | A1 |
20070110177 | Molander et al. | May 2007 | A1 |
20070127608 | Scheim et al. | Jun 2007 | A1 |
20070140330 | Allpress et al. | Jun 2007 | A1 |
20070213087 | Laroia et al. | Sep 2007 | A1 |
20070230593 | Eliaz et al. | Oct 2007 | A1 |
20070258517 | Rollings et al. | Nov 2007 | A1 |
20070291719 | Demirhan et al. | Dec 2007 | A1 |
20080002789 | Jao et al. | Jan 2008 | A1 |
20080049598 | Ma et al. | Feb 2008 | A1 |
20080080644 | Batruni | Apr 2008 | A1 |
20080130788 | Copeland | Jun 2008 | A1 |
20080260985 | Shirai et al. | Oct 2008 | A1 |
20080279298 | Ben-Yishai et al. | Nov 2008 | A1 |
20080279299 | Reuven et al. | Nov 2008 | A1 |
20090028234 | Zhu | Jan 2009 | A1 |
20090075590 | Sahinoglu et al. | Mar 2009 | A1 |
20090185612 | McKown | Jul 2009 | A1 |
20090290620 | Tzannes et al. | Nov 2009 | A1 |
20090323841 | Clerckx et al. | Dec 2009 | A1 |
20100002692 | Bims | Jan 2010 | A1 |
20100034253 | Cohen | Feb 2010 | A1 |
20100062705 | Rajkotia et al. | Mar 2010 | A1 |
20100115107 | Mitsuhashi et al. | May 2010 | A1 |
20100166050 | Aue | Jul 2010 | A1 |
20100202505 | Yu et al. | Aug 2010 | A1 |
20100284481 | Murakami et al. | Nov 2010 | A1 |
20100329325 | Mobin et al. | Dec 2010 | A1 |
20110074500 | Bouillet et al. | Mar 2011 | A1 |
20110074506 | Kleider et al. | Mar 2011 | A1 |
20110090986 | Kwon et al. | Apr 2011 | A1 |
20110164492 | Ma et al. | Jul 2011 | A1 |
20110228869 | Barsoum et al. | Sep 2011 | A1 |
20110310978 | Wu et al. | Dec 2011 | A1 |
20120207248 | Ahmed et al. | Aug 2012 | A1 |
20130028299 | Tsai | Jan 2013 | A1 |
20130044877 | Liu et al. | Feb 2013 | A1 |
20130121257 | He et al. | May 2013 | A1 |
Entry |
---|
Equalization: The Correction and Analysis of Degraded Signals, White Paper, Agilent Technologies, Ransom Stephens V1.0, Aug. 15, 2005 (12 pages). |
Modulation and Coding for Linear Gaussian Channels, G. David Forney, Jr., and Gottfried Ungerboeck, IEEE Transactions of Information Theory, vol. 44, No. 6, Oct. 1998 pp. 2384-2415 (32 pages). |
Intuitive Guide to Principles of Communications, www.complextoreal.com, Inter Symbol Interference (ISI) and Root raised Cosine (RRC) filtering, (2002), pp. 1-23 (23 pages). |
Chan, N., “Partial Response Signaling with a Maximum Likelihood Sequence Estimation Receiver” (1980). Open Access Dissertations and Theses. Paper 2855, (123 pages). |
The Viterbi Algorithm, Ryan, M.S. and Nudd, G.R., Department of Computer Science, Univ. of Warwick, Coventry, (1993) (17 pages). |
R. A. Gibby and J. W. Smith, “Some extensions of Nyquist's telegraph transmission theory,” Bell Syst. Tech. J., vol. 44, pp. 1487-1510, Sep. 1965. |
J. E. Mazo and H. J. Landau, “On the minimum distance problem for faster-than-Nyquist signaling,” IEEE Trans. Inform. Theory, vol. 34, pp. 1420-1427, Nov. 1988. |
D. Hajela, “On computing the minimum distance for faster than Nyquist signaling,” IEEE Trans. Inform. Theory, vol. 36, pp. 289-295, Mar. 1990. |
G. Ungerboeck, “Adaptive maximum-likelihood receiver for carrier modulated data-transmission systems,” IEEE Trans. Commun., vol. 22, No. 5, pp. 624-636, May 1974. |
G. D. Forney, Jr., “Maximum-likelihood sequence estimation of digital sequences in the presence of intersymbol interference,” IEEE Trans. Inform. Theory, vol. 18, No. 2, pp. 363-378, May 1972. |
A. Duel-Hallen and C. Heegard, “Delayed decision-feedback sequence estimation,” IEEE Trans. Commun., vol. 37, pp. 428-436, May 1989. |
M. V. Eyubog •Iu and S. U. Qureshi, “Reduced-state sequence estimation with set partitioning and decision feedback,” IEEE Trans. Commun., vol. 36, pp. 13-20, Jan. 1988. |
W. H. Gerstacker, F. Obernosterer, R. Meyer, and J. B. Huber, “An efficient method for prefilter computation for reduced-state equalization,” Proc. of the 11th IEEE Int. Symp. Personal, Indoor and Mobile Radio Commun. PIMRC, vol. 1, pp. 604-609, London, UK, Sep. 18-21, 2000. |
W. H. Gerstacker, F. Obernosterer, R. Meyer, and J. B. Huber, “On prefilter computation for reduced-state equalization,” IEEE Trans. Wireless Commun., vol. 1, No. 4, pp. 793-800, Oct. 2002. |
Joachim Hagenauer and Peter Hoeher, “A Viterbi algorithm with soft-decision outputs and its applications,” in Proc. IEEE Global Telecommunications Conference 1989, Dallas, Texas, pp. 1680-1686,Nov. 1989. |
S. Mita, M. Izumita, N. Doi, and Y. Eto, “Automatic equalizer for digital magnetic recording systems” IEEE Trans. Magn., vol. 25, pp. 3672-3674, 1987. |
E. Biglieri, E. Chiaberto, G. P. Maccone, and E. Viterbo, “Compensation of nonlinearities in high-density magnetic recording channels,” IEEE Trans. Magn., vol. 30, pp. 5079-5086, Nov. 1994. |
W. E. Ryan and A. Gutierrez, “Performance of adaptive Volterra equalizers on nonlinear magnetic recording channels,” IEEE Trans. Magn., vol. 31, pp. 3054-3056, Nov. 1995. |
X. Che, “Nonlinearity measurements and write precompensation studies for a PRML recording channel,” IEEE Trans. Magn., vol. 31, pp. 3021-3026, Nov. 1995. |
O. E. Agazzi and N. Sheshadri, “On the use of tentative decisions to cancel intersymbol interference and nonlinear distortion (with application to magnetic recording channels),” IEEE Trans. Inform. Theory, vol. 43, pp. 394-408, Mar. 1997. |
Miao, George J., Signal Processing for Digital Communications, 2006, Artech House, pp. 375-377. |
Xiong, Fuqin. Digital Modulation Techniques, Artech House, 2006, Chapter 9, pp. 447-483. |
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20140133608 A1 | May 2014 | US |
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61726099 | Nov 2012 | US | |
61729774 | Nov 2012 | US | |
61747132 | Dec 2012 | US | |
61768532 | Feb 2013 | US | |
61807813 | Apr 2013 | US |