A technique used for digital information detection in so-called, Soft Interference Cancellation (SIC) receivers relies on iterative feedback of log likelihood ratio signals (LLR's) and progressively improved estimations of the more likely bit sequences to have been received through a noisy channel given a known constellation of the symbols representing those bit sequences. Within this technique, it is necessary to determine soft symbol means and variances of the constellation symbols. However, circuitry for generating the soft symbol means and variances tends to be large, complex and slow in performance.
Circuits for producing signals representative of mean and variance estimation of quadrature amplitude modulation (QAM) symbols as used for example in SIC receivers are provided where the circuit comprises: sequentially repeated first circuit modules for producing iterative updates of Xi values (ξ's) and/or Zeta values (ζ's) used in a corresponding estimation iteration; and sequentially repeated second circuit modules for producing iterative updates of Eta values (η's) used in the corresponding estimation iteration.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
Log-likelihood ratio signals (LLR's) provide a comparison between two model outcomes. Because it is based on a logarithm of the ratio of probabilities (likelihoods; e.g., L1/L2), if the two probabilities are the same, the log of their ratio is zero (Log(1)=0). If the numerator probability is greater, meaning the ratio is greater than one, the log of the ratio is positive. If the denominator probability is greater, meaning the ratio is less than one, the log is negative. Thus the sign of the result gives an indication of which model provides a better fit for given conditions and the absolute value gives an indication of degree that one model is better than the other. For the case where the competing models are that of a binary bit being zero or one, the LLR is the logarithm of the ratio of the probability of the bit being zero over the probability of the bit being one.
Still referring to
The modulated signal X (108) is then applied to the multiple output transmitter 110 which in one embodiment has a plurality of spaced apart radio frequency antennas 111 from which there are emitted a corresponding plurality of spread spectrum signals X1 through Xn for transmission through the channel 115 and receipt by another plurality of spaced apart antennas 121 where the received signals are represented respectively by phase/amplitude vectors y1 through yn. The corresponding MIMO receiver 120 demodulates the received signals and passes them to an FEC decoder 124. A first output of the decoder represents the reconstructed data stream 124a (e.g., bit sequence b1″, b2″, b3″, . . . ). A second output of the decoder provides a feedback 124b of log-likelihood ratio signals (LLR's) which are also represented here in by the Greek letter lambda (λ). In one embodiment, before final decisions are reached on the bits of the reconstructed data stream 124a (e.g., bit sequence b1″, b2″, b3″, . . . ), a plurality of iterations are used in conjunction with the fed back LLR signals (e.g., λ1, λ2, λ3, . . . ) so as to get a better estimation of what the reconstructed binary bits should be (either a “0” or a “1”). In
Referring to
By way of explanatory mathematics, the process may be depicted by a receiver model:
where H is a channel transform determined by use of pilot signals and n represents a noise vector. Differences between the received signal vectors can be used to provide for soft interference cancellation:
The original signal can be reconstructed at the receiver side with use of LMMSE filtering:
where the cross symbol represents . . . . Within the process, the following mean and variance determinations are made:
{tilde over (x)}i=E{xi}
{tilde over (σ)}j2=var{xj−{tilde over (x)}j}=E{|xj|2}−|{tilde over (x)}j|2
Referring the next to
In one published paper (**), per single axis (e.g. Q or I) mean estimation has been proposed to be determined by use of a pipelined iteration process (Iteration 1):
** “Iterative MMSE-SIC Receiver with Low-Complexity Soft Symbol and Residual Interference Estimations” by Guosen Yue et al, (NEC Laboratories America, Inc., Princeton, N.J. 08540) IEEE Asilomar 2013, incorporated here by reference.
This first iteration process may be carried out by the circuitry 300 shown in
Next and still referring to
In accordance with the first proposed iteration process as carried out by the circuitry 300 of
Referring next to the plots of
In
Before examining the details of
Referring to
More specifically, it is recognized in
For the case of Q2 and step 2, the corresponding Xi values (ξ's) can be generated by applying the corresponding Bit LLR's ((λ2's) to a second tan h( ) generating circuit block 422 configured to produce a corresponding tan h(−λ/2) signal for the respective input signals where the latter signals are applied as first multiplicands to a general purpose second digital multiplier 425 while the Xi values (ξ's) of step 1 are applied as second multiplicands to the same general purpose digital multiplier 425. The outputs of the second digital multiplier 425 are supplied to a first digital adder 427. A second input of the first digital adder 427 receives a left shifted (by one bit) and zero padded version of the Eta values (η's) of step 1 to thereby form the Eta values (η's) for the case of Q2 and step 2. Although a multiply by 2 symbol is shown at 426, it is to be understood that this function is can be performed with a minimized circuit that simply shifts its received bits by one bit place and inserts a padding zero bit at the least significant bit location (LSB) of its output. A general purpose, normalizing multiplier 428 receives the Eta values (η's) for the case of Q2 and step 2 as first multiplicand inputs and receives as another multiplicand input the negatively signed A16QAM signal and produces the corresponding 16QAM_out signal for optional use when 4×4 quadrature amplitude modulation is used.
It is to be noted that when the Eta values (η's) of step 1 are multiplied by 2 (e.g., by shift circuit 426) and thereafter supplied into the addition performed by adder circuit 427, the significance of that x2 addend becomes relatively more important to the addition result and conversely, the significance of the next addend in the chain (e.g., the one obtained from multiplier 425) becomes relatively less important to the addition result. Moreover, the products of multipliers 425, 435, 445, etc. are those of multiplying by values all less than one so that as the chain of multiplications continues, the absolute values of the products keep shrinking.
Similarly, for the case of Q3 and step 3, the corresponding Xi values (ξ's) can be generated by applying the corresponding Bit LLR's ((λ3's) to a third tan h( ) generating circuit block 432 configured to produce a corresponding tan h(−λ/2) signal for the respective input signals where the latter signals are applied as first multiplicands to a general purpose third digital multiplier 435 while the Xi values (ξ's) of step 2 are applied as second multiplicands to the same digital multiplier 435. The outputs of the second digital multiplier 435 are supplied to a second digital adder 437. A second input of the second digital adder 437 receives a left shifted (by one bit) and zero padded version of the Eta values (η's) of step 2 to thereby form the Eta values (η's) for the case of Q3 and step 3. Once again, although a multiply by 2 symbol is shown at 436, it is to be understood that this function can be performed with a minimized circuit that simply shifts its received bits by one bit place left and inserts a padding zero bit at the least significant bit location (LSB) of its output. A general purpose, normalizing multiplier 438 receives the Eta values (η's) for the case of Q3 and step 3 as first multiplicand inputs and receives as another multiplicand input the negatively signed A64QAM signal and produces the corresponding 64QAM_out signal for optional use when 8×8 quadrature amplitude modulation is used.
Moreover, and yet again in repeating circuit structure fashion, for the case of Q4 and step 4, the corresponding Xi values (ξ's) can be generated by applying the corresponding Bit LLR's (λ4's) to a third tan h( ) generating circuit block 442 configured to produce a corresponding tan h(−λ/2) signal for the respective input signals where the latter signals are applied as first multiplicands to a general purpose, fourth digital multiplier 445 while the already produced Xi values (ξ's) of step 3 are applied as second multiplicands to the same general purpose digital multiplier 445. The outputs of the third digital multiplier 445 are supplied to a third digital adder 447. A second input of the third digital adder 447 receives a left shifted (by one bit) and zero padded version of the already produced Eta values (η's) of step 3 to thereby form the Eta values (η's) for the case of Q4 and step 4. Once again, although a multiply by 2 symbol is shown at 446, it is to be understood that this function is can be performed with a minimized circuit that simply shifts its received bits by one bit place left and inserts a padding zero bit at the least significant bit location (LSB) of its output. A general purpose, normalizing multiplier 448 receives the Eta values (η's) for the case of Q4 and step 4 as first multiplicand inputs and receives as another multiplicand input the negatively signed A256QAM signal and produces the corresponding 256QAM_out signal for optional use when 16×16 quadrature amplitude modulation is used.
Although most of the circuitry 400 of
Moreover, although the circuitry 400 of
Comparing circuit 300 of
The simulated block error processing results of
Referring to
One method for approximating or rounding |tan h( )| to a corresponding 2−k value is explained as follows. For values of index i |tan h(−λi/2)|, denoted as |φi|, since |φi|≤1, it can be represented in hardware (or quantized with the fixed point representation) by Σkai,k2−k, ai,kϵ{0,1}. Then for a |φi|, in the production, one can first find the first non-zero bit, ai,k′
The circuitry 502 of
The second comparator/selector 539a is provided and configured to determine which of unsigned tan h signals 534 and the one supplied from 529a is the bigger one and which is the smaller one and to route the smaller one to rounding circuit 539b while routing the bigger one to special purpose multiplier 535. Rounding circuit 539b rounds its received result to a base 2 valuation in the range 0.00 to 1.00 and supplies the rounded (approximated) digital result signal to one input of multiplier 535. Multiplier 535 also receives a sign specifier from special purpose multiplier 543. Multiplier 525 similarly receives a sign specifier from multiplier 542. Multiplier 515 receives its sign specifier from sign detector 513. Multiplier 535 is deemed a special purpose multiplier because only one of its inputs is a general purpose multiplicand input (the r0.5 resolution signal from comparator/selector 539a). Two further inputs of the special purpose multiplier 535 receive respective integer k values from respective rounder identifying units 539b and 529b where the respective integer k values (e.g., k=1, 2 or 3) indicate how many bit places to the right the general purpose multiplicand will be shifted with insertion of zero bits at the emptied spots. A fourth input signal of the special purpose multiplier 535 is the polarity reversal indicating one (obtained from multiplier 543 as mentioned above). After the respective right bit place shifts are performed on the received general purpose multiplicand signal (of initial resolution r0.5 bits) its polarity is selectively flipped or not based on the polarity reversal indicating signal. Thus no general purpose multiplication occurs in special purpose multiplier 535. Just rightward bit shifting and optional polarity reversal is performed. Accordingly, special purpose multiplier 535 can be implemented as smaller and faster circuitry than a general purpose multiplier.
Similarly for the case of multiplier 525, it is deemed a special purpose multiplier because only one of its inputs is a general purpose multiplicand input (the r0.5 resolution signal from comparator/selector 529a). A further input of the special purpose multiplier 525 receives a respective integer k value from respective rounder identifying units 529b where the respective integer k value (e.g., k=1, 2 or 3) indicates how many bit places to the right the general purpose multiplicand will be shifted with insertion of zero bits at the emptied spots. A third input signal of the special purpose multiplier 525 is the polarity reversal indicating one (obtained from multiplier 542 as mentioned above). Thus no general purpose multiplication occurs in special purpose multiplier 525. Just rightward bit shifting and optional polarity reversal is performed. Accordingly, special purpose multiplier 525 can be implemented as smaller and faster circuitry than a general purpose multiplier.
Multiplier 516 multiplies the output of multiplier 515 by 4 (e.g., using a left shift factor of 2 bit places) to produce the Eta value (η) for the case of Q=1 and step 1. Multiplier 526 multiplies the output of multiplier 525 by 2 (e.g., using a left shift factor of 1 bit place) to produce the Eta value (η) for the case of Q=2 and step 2. Multiplier 535 directly produces the Eta value (η) for the case of Q=3 and step 3. Respective sums of Eta values (η's) are produced by digital adders 527 and 537 for the respective cases of Q=2 and Q=3. Multiplier 538 normalizes the result for the case of Q=3.
Continuing with reference to the tan h(x) function graph 501 of
More specifically, given three values on the plot, say tan h(x1), tan h(x2) and tan h(x3), and assuming |tan h(x1)|>|tan h(x2)|, the system automatically picks the |tan h(x2)| output as the one that will undergo approximation. Then, the system compares the larger one of |tan h(x1)| and |tan h(x2)|, which is now |tan h(x1)| based on the assumption, with |tan h(x3)|, the system may pick the smaller one of |tan h(x1)| and |tan h(x3)| outputs as the ones that will undergo approximation by rounding it to the closest largest 2−k2, and finally after two comparisons, the largest one of |tan h(x1)|, |tan h(x2)|, |tan h(x3)| is selected as the one that will not undergo approximation.
More specifically, in the case of
It is to be noted that the outputs of the rounder circuits, 529b and 539b, are of lower bit resolution than the resolutions r0.5 of the half sized LUT's. This smaller resolution is denoted in
Referring to
Referring to
In
Referring to
Responsive to the determination made at step 702, in subsequent step 703 a coupling is made to the corresponding Q output tap in a multiply-tapped mean estimating circuit such as that of any one of
The tapped mean and second moment estimating circuits are then used for generating and storing corresponding mean and second moment estimations for the determined Q parameter value. Then, in step 705 it is determined that all of the currently desired mean and second moment estimation signals for the current Q parameter value have been collected. The system is reset so as to be able to re-use the same mean and moment estimating circuits for a next commanded, Q parameter value. Control then loops back to step 7024 receiving the next commanded, Q parameter value.
Referring to
Using a predetermined performance comparison chart or graph (e.g., such as the graph in
Justifications for the development of the scalable recursive methods may be explained by the following.
It is possible to provide low-complexity methods for generating mean and variance signals for use in QAM estimation with applications to SIC receivers. In particular, the present disclosure provides efficient methods for optimal estimations that facilitate less circuitry in the hardware implementation and also make the implementation scalable to any Gray mapped PAM or QAM modulations. For variance estimation or specifically the second moment estimation, the proposed method reduces the complexity from O((log N)2) in earlier used methods to O(log N) in the here disclosed methods. The disclosure also provides several alternative suboptimal methods for generating the soft QAM symbol mean and variance signals which methods avoid general purpose multiplications in the hardware implementations and replace them with simply binary shifts. In some instances, the disclosed approximation approaches provide similar or better block error (BLER) versus SNR performance than earlier methods but with simpler implementation and less logical circuitry.
An iterative receiver with soft interference cancellation (SIC) can provide near optimal performance for joint demodulation and decoding. An example of such an iterative receiver, or so-called turbo receiver, has been applied to equalization as set forth in M. Tüchler, R. Koetter, and A. C. Singer, “Turbo equalization: Principles and new results,” IEEE Trans. Commun., vol. 50, no. 5, pp. 754-767, May 2002. Another example of such an iterative receiver has been applied to multiuser detection as set forth in X. Wang and H. V. Poor, “Iterative (turbo) soft interference cancellation and decoding for coded CDMA,” IEEE Trans. Commun., vol. 47, no. 7, pp. 1046-1061, July 1999. Yet another example of such an iterative receiver has been applied to a Multiple-Input and Multiple-Output (MIMO) receiver as set forth in B. M. Hochwald and S. ten Brink, “Achieving near-capacity on a multiple-antenna channel,” IEEE Trans. Commun., vol. 51, no. 3, pp. 389-399, March 2003.
From the LTE base station side, an iterative receiver with SIC can be applied to LTE uplink single-carrier frequency division multiple access (SC-FDMA) as set forth for example in T. Li, W. Wang, and X. Gao, “Turbo equalization for LTE uplink under imperfect channel estimation,” in Proc. Personal, Indoor, and Mobile Radio Commun. (PIMRC), Tokyo, Japan, September 2009. It can be applied to uplink multiuser MIMO as set forth in M. Jiang, G. Yue, N. Prasad, and S. Rangarajan, “Link adaptation in LTE-A uplink with turbo SIC receivers and imperfect channel estimation,” in Proc. Conf. Info. Sci. Syst. (CISS), Baltimore, Md., March 2011. It can further be applied to uplink coordinate multipoint (CoMP) reception with SIC (CoMP SIC).
One key operation in SIC type iterative receivers is that of real time generating of soft mean and variance signals for QAM estimations when provided with the log-likelihood ratios (LLR) of the coded bit sequence from the decoding outputs. When considering how to reduce complexity of SIC receivers, it is worthwhile to consider efficient approaches for soft symbol mean and variance determination. This can become particularly important for higher order quadrature symbol constellations QAM, e.g., 256-QAM in Release-12 LTE systems, or 4096-QAM in microwave transmissions. It has been shown for example in G. Yue, N. Prasad, and S. Rangarajan, “Iterative MMSE-SIC receiver with low-complexity soft symbol and residual interference estimations,” in Proc. 39th Asilomar Conf. Signals, Systems and Computers, Pacific Grove, Calif., October 2013 (hereafter also “[reference 8]”) that for a given QAM, symbol determination can be reduced in the order of the number of the bits that are mapped to the QAM symbol for the mean calculation and square of that for the variance calculation. The results may be derived by goal-ended reorganization of the signal processing operations performed on in-stream signals. Therefore, there is no performance loss in spite of the reorganization of the signal processing operations. However, from the resulting expressions, some general purpose multiplication operations on outputs of tan h functions still exist. A suboptimal approach is also proposed in G. Yue, N. Prasad, and S. Rangarajan, “Iterative MMSE-SIC receiver with low-complexity soft symbol and residual interference estimations,” in Proc. 39th Asilomar Conf. Signals, Systems and Computers, Pacific Grove, Calif., October 2013 for removing general purpose multiplication operations to further reduce complexity. However, the suboptimal approach does not consider the different reliabilities of the bits of a QAM symbol and treat them equally rather than based on probabilities of correct decision.
In this disclosure, several efficient methods for optimal estimations are proposed which facilitate less circuitry in the hardware implementation and further reduce complexity of variance estimation. The present disclosure also proposes several alternative suboptimal methods which also avoid use of general purpose multiplication operations in processing the products of tan h outputs.
(2.1) The Signal Model
As an example, consider an iterative SIC receiver with minimum mean square error (MMSE) filtering for use in a MIMO system having MT transmit antennas and MR receive antennas. Assume MR≥MT. Denote x=[x1, . . . , xM
where H=[h1, . . . , hM
(2.2) Iterative MMSE-SIC Receiver
Given as inputs, the extrinsic log-likelihood ratios (LLRs) of the coded bits from the soft channel decoder in the previous iteration, it is possible to obtain the soft estimation of the QAM symbol xi, denoted as {tilde over (x)}i=E{xi}, i=1, . . . , MT. To improve the detection of the ith QAM symbol xi, it is possible to perform the SIC for QAM symbols xj, j≠1. The result signal is then given by following equation (2):
The linear MMSE filter can then be obtained, given by (3):
where † denotes matrix Hermitian, Σj≠1{tilde over (σ)}j2 hj hj\ is covariance of the residual interference after SIC, and then square variance is provided by (4):
{tilde over (σ)}j2=var{xj−{tilde over (x)}j}=E{|xj|2}−|{tilde over (x)}j|2. (4)
With that the MMSE-SIC filtering output is then given by (5):
{tilde over (x)}i=wi\yi. (5)
Assuming that {tilde over (x)}i is Gaussian distributed, it is possible to then obtain the LLR's for the binary labeling bits that are mapped to the QAM symbol xi and send the extrinsic information to the soft channel decoder. The output extrinsic LLR's from the soft decoder are then fed back as the prior LLR's for a next iteration of MMSE-SIC. Initially, the iterative process may start with a soft estimate of {tilde over (x)}i=0. Details for a general iterative MMSE-SIC receiver can be found in G. Yue and X. Wang, “Optimization of irregular repeat accumulate codes for MIMO systems with iterative receivers,” IEEE Trans. Wireless Commun., vol. 4, no. 6, pp. 2843-2855, November 2005.
It can be seen from above that for a SIC iterative receiver, it is possible to obtain the soft QAM estimation, {tilde over (x)}i, and the variance of the QAM symbol {tilde over (σ)}i2 for purpose of estimation of the residual interference. It may be see is seen from equation (4) that when the soft estimation {tilde over (x)}i is obtained, a further problem left for the variance estimation operation is the estimation of the second moment of the QAM symbol, E{|xj|2}.
(3.1) Definitions
A set of symbols may be distributed in a n×m (=N) quadrature constellation, for example as the N-QAM constellation set SQAM={s1, . . . , sN}, with each symbol mapped from a length-J binary sequence, b1, . . . , bj, where J=log2 N and biϵ{0,1}. It may be assumed that the QAM symbols are integer values on I and Q axis components, i.e., 2z+1, z=0, ±1, . . . . It is possible to then normalize the QAM signal for a unit average power with the scaling factor of
where EN is the variance of the QAM inputs. Assuming equiprobable inputs, then the following normalized power can be given in accordance with equation (6):
(3.1.1) Mean Estimation
Given an LLR named λi then for bi, i=1, . . . , J, mapped to the QAM symbol xqamϵSQAM, it is possible to then form the soft symbol or the mean estimation of xqam per equation (7):
where sn,i denotes the ith bit in the length-J bit sequence that is mapped to the QAM symbol sn,
iϵ{0,1}, and
It can be seen that the overall complexity is O(N log N).
For a square QAM constellation with orthogonal mapping of I and Q components, the QAM symbol estimation can be decoupled into two, one dimensional pulse-amplitude modulation (PAM) estimations, each given by following equation (8):
where
and sn,j is now the ith bit mapped to the PAM symbol sn. It can be seen that PAM estimation in equation (8) requires QN′ multiplications and N′−1 additions. Thus overall the squared QAM estimation needs 2Q√{square root over (N)} multiplications and 2√{square root over (N)}−2 additions. The complexity order is then O(√{square root over (N)} log N), which is lower than the above given value of O(N log N).
(3.1.2) Variance Estimation
As described in above Section 2, after obtaining the soft symbol estimate, the estimation of the variance of the residual interference after SIC becomes the second moment estimation. The general definition of the second moment estimation is given per equation (9):
where
sI and SQ denote the I and Q values of the QAM symbol s, respectively. The complexity of the estimation using the above expression is O(N log N).
Similarly as for mean estimation, we consider the squared QAM which can be decoupled to two orthogonal PAMs. Assuming an N′-PAM constellation set SPAM={s1, . . . , sN′} with N′=2Q, it is possible to then have the second moment estimation for PAM symbols given in accordance with following equation (10):
The above equation (10) can be applied to obtain {tilde over (v)}12 and {tilde over (v)}Q2 in equation (9) separately. The complexity is then reduced to O(√{square root over (N)} log N).
(3.2) Approaches for Gray Mapped QAM Symbols
Referring to G. Yue, N. Prasad, and S. Rangarajan, “Iterative MMSE-SIC receiver with low-complexity soft symbol and residual interference estimations,” in Proc. 39th Asilomar Conf. Signals, Systems and Computers, Pacific Grove, Calif., October 2013, and by reordering the signal processing operations, the expressions for the efficient mean and variance estimations can be obtained for both squared QAM and non-squared QAM. Consider the squared QAM as an example. For squared QAM, the soft mean and variance (or specifically the second moment) estimation can be decoupled to two PAM estimations. Also consider the
(3.2.1) Mean Estimation
For a 2Q-PAM symbol with Gray mapping as shown in the BRGC mapping 900 of
Note that the above result is derived for PAM symbols 2z+1 before normalization for unit average power. After that, a scaling factor
is applied for both I and Q components for QAM normalization.
Based on above equation (11), an iterative digital processing operation for soft PAM estimation can then be formed as follows.
Since the hyperbolic tangent function tank can be implemented by a look-up table (LUT), the overall complexity for above soft PAM estimation algorithm can be made very low, e.g., in the order of log N. Note that all the multiplications with 2i can be implemented with bit shifting and padding in of zeros for locations from which original bits were shifted out. Thus the associated complexity for such bit shifting operations can be ignored.
3.2.2 Variance Estimation
As aforementioned, for variance estimation, it is possible to determine the second moment estimation {tilde over (v)}2 for a PAM symbol. An efficient expression is derived in [reference 8]. Given the LLRs λi, i=1, . . . , Q, the second moment estimate {tilde over (v)}2 for a 2Q-PAM symbol with Gray mapping can be determined in accordance with the following equation (12):
where CQ is a constant depending on Q and can be obtained iteratively by following equation (13):
Cq=4Cq−1+1, q=1, . . . , Q, with C0=0. (13)
The estimation in equation (12) is before the normalization. After the estimation, the normalization factor
is then applied for the N-QAM modulation.
In [reference 8] an iterative digital processing operation based on equation (12) to obtain {tilde over (v)}2 can then be derived as follows.
(3.2.3) Examples
The mean and second moment estimation of 4-PAM (corresponding to one axis of a 4λ4=16QAM constellation) before normalization can be respectively given by:
The mean and second moment estimation of an 8-PAM (corresponding to 8×8=64QAM) before normalization can be respectively given by:
The mean and second moment estimation of a 16-PAM (corresponding to 16×16=256QAM) before normalization can be respectively given by:
(3.3) Simplified Hardware Implementation Procedures
(3.3.1) Mean Estimation
Instead of the complex procedures described in Section 3.2.1, the data processing operations are changed to provide the following iterative procedure:
Referring to
For example, the implementation according to the procedures in Section 3.2.1 can be represented by the circuitry shown in
for an N-QAM. It is seen from
3.3.2 Variance Estimation
Method 1:
Similar to the way that simplification is provided for mean estimation, it is possible to make the following changes in the iteration process for determining the second moment estimation as follows.
It can be seen that that with the above changes, the digital data processing operations do not have Q dependent parameters. The procedures can be efficiently implemented similar to the mean estimation. It is then also scalable for larger values of Q with the predetermined values for smaller Q stored and thus reusable.
Method 2:
By carefully examining the result in equation (12), another data processing algorithm per we now propose the following can be used to further reduce the computation complexity to the order O(log N) from O((log N)2) where the latter are more complex order is needed in [reference 8].
It can be seen that the inner iteration from Method 1 has been removed. The additional complexity introduced is the addition operation of +1 when updating the Zeta ζ in each iteration. If it is difficult from Method 1 to see the scalability for different QAM modulations, but it thereafter becomes clearer in
(4) Suboptimal Approaches for Hardware Implementations
The approaches described in Section 3 are optimal for both soft mean and variance estimations. To further reduce the complexity, the suboptimal approach with approximations can be considered to avoid multiplications that are more complex than additions in hardware implementations. It can be seen that in equations (11) and (12), the majority part for the complexity is the generating of the products of the tan h( ) functions. An example of the mean estimation according to equation (11) is shown in
(4.1) Approximation Approaches
The basic idea is to find an approximation for the product of tan h functions, e.g.,
A method is provided in [reference 8] and recapitulated as follows.
Mathematically, this provides the following equation (14):
(4.2) Proposed Suboptimal Approaches
A couple of alternative suboptimal approaches are proposed below which can simplify the hardware implementations. For some approaches, it has been found by simulation that the simplified approaches may provide better receiver BLER vs. SNR performance than the more complex approaches.
(4.2.1) Alternative Method I
It is seen that the approximation provided in [reference 8] treats the binary bits mapped as QAM symbols equally. It does not consider different reliability of the bits after the demodulations due to different average Euclidean distances for the labeling bits. It is known that the more significant bit, e.g., the bi in the bit sequence for the 4-PAM or 8-PAM as shown in the above bit significance tree has the most reliable LLR statistically because of large average Euclidean distance of the PAM symbols for this bit. Thus in the first approach, it is proposed that the approximation of the production of tan h be as follows. Assuming the same bit labeling order as shown in tree chart, the bit significance for a Gray mapped PAM symbol from high to low is b1, b2, . . . , bQ. Thus in the production of tan h, since the one with the lowest index has the highest reliability, the process can then retain the tan h value for the most significant bit in the production for the production, and approximate other values to a nearest 2−k value in the range −1 to +1. The procedure is described as follows.
Mathematically, this gives the following equation (15):
Since the selection is deterministic for every production of tan h, the implementation can then be simplified and it is also scalable to any QAM modulations. The schematic is shown in
Saturation Protection:
Since tan h(x) is in the range of [−1,+1], when the absolute value |λi| is large, the value of tan h(−λi/2) is easily saturated, particularly for the higher reliable labeling bit. It is then inefficient to retain the saturated value and approximate other tan h outputs. To overcome this inefficiency, it is proposed to add a protection to the implementation as follows.
For fixed point implementation with quantized LLR, the threshold δth can be set to 1.
4.2.2 Alternative Method II
This alternative method is based on the thought that the least significant bit creates the most residual interference for the last several iterations. So instead of retaining the value of ψi for the most reliable bit, it is proposed to keep the one for the least reliable bit, i.e., least significant bit in the bit sequence in a production tan h. The Method II is summarized as follows.
Mathematically, the following equation (16) is obtained:
The resulting implementation is illustrated in
Note that the approximation approach method in [reference 8] and proposed Method I may not be suitable for the Method 2 for the second moment estimation. However, the proposed Method II can be applied to the Method 2 for the second moment estimation, which makes this approximation method more attractive.
(5) Numerical Simulation Results
Referring to
Although the subject matter has been described in language specific to structural features and/or methodological acts, it is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.
Number | Name | Date | Kind |
---|---|---|---|
20060140295 | Jeong | Jun 2006 | A1 |
20070041475 | Koshy | Feb 2007 | A1 |
20120155560 | Koshy | Jun 2012 | A1 |
20130279559 | Samuel Bebawy | Oct 2013 | A1 |
20140270023 | Yue | Sep 2014 | A1 |
20150078183 | Cao et al. | Mar 2015 | A1 |
20160110201 | Carlson | Apr 2016 | A1 |
Number | Date | Country |
---|---|---|
103326976 | Sep 2013 | CN |
2006066445 | Jun 2006 | WO |
Entry |
---|
Yue et al., “Iterative MMSE-SIC Receiver with Low-Complexity Soft Symbol and Residual Interference Estimations”, 2013 Asilomar Conference on Signals, Systems and Computers, IEEE, Nov. 2013, 5 pages. |
Yue et al., “Low-Complexity Methods for Soft Estimation of QAM Symbols”, 2013 47th Annual Conference on Information Sciences and Systems (CISS), Mar. 20-22, 2013, 6 pages. |
PCT/CN2017/076121, ISR, dated Jun. 12, 2017. |
Number | Date | Country | |
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20170264478 A1 | Sep 2017 | US |