1. Field of the Invention
The present invention relates generally to methods, devices, and systems to select a transmit antenna by accounting for errors in feedback from a receiver. The present invention also relates to methods, devices, and systems to identify the transmit antenna at a receiver.
2. Discussion of the Background
While multiple-input multiple-output (MIMO) systems may yield remarkable improvements in both data transmission rates and the reliability of transmission over wireless channels without requiring any additional bandwidth, their widespread adoption has been inhibited by issues such as increased hardware and signal processing complexity. This is because each transmit antenna requires a dedicated radio frequency (RF) chain that includes a digital-to-analog (D/A) converter, a frequency-up converter, and a power amplifier. At the same time, each receive antenna requires an RF chain that comprises a low noise amplifier (LNA), a frequency-down converter and an analog-to-digital (AID) converter.
Generally speaking, antenna selection is a low-complexity technique that reduces the hardware complexity of MIMO systems. A selection switch enables the use of a subset of the available antennas for data transmission or reception. Therefore, fewer RF chains than the total number of available antennas are required. Even so, it has been shown that under ideal conditions antenna selection can achieve the full diversity order of the wireless channel in several systems.
Receive antenna selection (RAS) has been studied in single input multiple output systems (SIMO) and for MIMO channels. Transmit antenna selection (TAS) has also received more attention recently. For lower-rank wireless channels, TAS may increase the data transmission rate compared to the transmitters that do not have access to channel state information (CSI).
Feedback from a receiver is useful when implementing TAS, as the CSI is often not readily available at the transmitter. This is because the short-term fading in the forward and reverse channels is typically uncorrelated in frequency division duplex systems (FDD) systems. Even in time division duplex (TDD) systems, in which the transmitter can infer the channel state from reverse link transmissions, the CSI may be unreliable at higher Doppler frequencies, or when the forward and reverse link interferences are asymmetric. To minimize overhead, the receiver generally does not feed back the entire channel state. Rather, the receiver determines and feeds back the indices of the antennas that the transmitter should select (e.g., the receiver feeds back a codeword that can be mapped to the antennas to be selected). To optimize overall system performance, the bit rate allowed on the feedback channel and the complexity of the signal is typically severely limited. For example, in third generation (3G) cellular telephone systems, the feedback is uncoded and the bit rate is just 1.5 kbps. Therefore, bit error rates of the feedback can be as high as 4%. While error correction coding can be used to reduce this error rate, the extra bits required for error correction increase the feedback latency and significantly reduce the maximum Doppler frequency that the system can handle.
In the prior art, techniques for antenna selection have often assumed that feedback is error-free and instantaneous. Additionally, those techniques have assumed that the communication channels are uncorrelated. The inventors of the present invention have determined that these assumptions are not always accurate.
In light of these difficulties, the Applicants developed the present invention. To this end, a non-limiting aspect of the present invention provides a method for receiving data at a receiver via a communication channel from a transmitter having at least two transmitter antennas, the method including: receiving a codebook including an assignment of at least two respective codewords to the at least two transmitter antennas, the assignment being based at least in part on a characteristic of the communication channel; detecting a state of the communication channel by which the transmitter can transmit to the receiver; selecting at least one desired transmitter antenna from the at least two antennas based at least in part on the detected state of the communication channel; transmitting to the transmitter a codeword corresponding to the at least one desired transmitter antenna; and receiving data at the receiver transmitted by the transmitter.
Another non-limiting aspect of the present invention includes a method performed in a system in which a transmitter transmits data to a receiver using at least one of at least two transmitter antennas and a communication channel, the method including: determining a correlation between a first antenna element of the at least two transmitter antennas, which is assigned a first codeword, and a second antenna element of the at least two transmitter antennas; and assigning a second codeword to the second antenna element based at least in part on a Hamming distance between a first bit sequence representing the first codeword and a second bit sequence representing the second codeword and at least in part on the determined correlation.
The present invention also includes, as a non-limiting embodiment, a method for transmitting data in a system in which a transmitter having at least two transmitter antennas transmits data to a receiver via a communication channel using at least one of the at least two antennas, the method including: transmitting to a receiver a codebook which includes an assignment of at least two respective codewords to at least two of the at least two transmitter antennas, the assignment being based at least in part on a characteristic of the communication channel; receiving at the transmitter a codeword corresponding to at least one desired transmitter antenna; and transmitting data to the receiver using at least one actual transmitter antenna corresponding to the received codeword.
The present invention also provides as another non-limiting aspect a system in which a transmitter having at least two transmitter antennas transmits data to a receiver via a communication channel using at least one of the at least two transmitter antennas, the system including: the transmitter configured to transmit a codebook which includes an assignment of at least two respective codewords to at least two of the at least two transmitter antennas, the assignment being based at least in part on a characteristic of the communication channel; the receiver configured to receive the codebook, to select a codeword corresponding to at least one desired transmitter antenna, and to transmit the selected codeword to the transmitter; and the transmitter further configured to transmit data to the receiver using at least one actual transmitter antenna corresponding to the codeword received at the transmitter from the receiver.
Yet another non-limiting aspect of the present invention provides a computer program product storing a computer program which when executed by a processor in a radio network causes the processor to perform steps of: receiving a codebook including an assignment of at least two respective codewords to at least two transmitter antennas, the assignment being based at least in part on a characteristic of a communication channel; detecting a state of the communication channel by which a receiver can communicate with the transmitter; selecting at least one desired transmitter antenna from the at least two antennas based at least in part on the detected state of the communication channel; transmitting to the transmitter a codeword corresponding to the at least one desired transmitter antenna; and receiving data at the receiver transmitted by the transmitter.
Another non-limiting aspect of the present invention includes a computer program product storing a computer program which when executed by a processor in a radio network causes the processor to perform steps of: determining a correlation between a first antenna element of at least two transmitter antennas, which is assigned a first codeword, and a second antenna element of the at least two transmitter antennas; and assigning a second codeword to the second antenna element based at least in part on a Hamming distance between a first bit sequence representing the first codeword and a second bit sequence representing the second codeword and at least in part on the determined correlation.
Still further, the present invention includes, as a non-limiting aspect, a computer program product storing a computer program which when executed by a processor in a radio network causes the processor to perform steps of: transmitting to a receiver a codebook which includes an assignment of at least two respective codewords to at least two transmitter antennas, the assignment being based at least in part on a characteristic of the communication channel; receiving at the transmitter a codeword corresponding to at least one desired transmitter antenna; and transmitting data to the receiver using at least one actual transmitter antenna corresponding to the received codeword.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
a) is a scatter plot of the simulated Pe(γ, μ) and the metric Mver(μ; γ),
b) is a scatter plot of the average SEP from simulations and the metric Mno-ver(μ; γ), defined in (27), for no-selection verification;
a) is a graph comparing the SEP performance of μver* and μno-ver*;
b) is a graph comparing the performance of the different signaling assignments for different number of receive antennas for Nt=16;
a) is a graph comparing SEP performance of the blind optimal symbol-level selection verification receiver (line) and the blind suboptimal symbol-level selection verification receiver (dot) for the two signaling assignments μver* and μno-ver*;
b) is a graph of Pver(T) and Pver(R) using the signaling assignment μver*;
a) and 6(b) are graphs comparing the average SEP and Pver(T) of symbol-level and block-level detection;
a) and 7(b) are graphs comparing the SEP and P(T)ver of non-blind optimal selection verification with ideal selection verification and no-selection verification for Nt=8, Lt=1, and Nr=1;
a) and 8(b) are graphs of non-blind optical antenna selection verification as a function of α with μver* as the signaling assignment;
By way of example in the following explanation of non-limiting aspects of the present invention, the symbol (.)T denotes a matrix transpose, (.)† a Hermitian transpose, ∥.∥ a norm of a vector, and ∥.∥F a Frobenious norm. The symbol Ca×b denotes a set of a×b complex matrices. EA|B [.] denotes an expectation over a random variable (RV) A given B. Pr(A|B) denotes a conditional probability of A given B if A is a discrete RV, and p(A|B) denotes a probability distribution function (pdf) of A given B if A is a continuous RV.
In step S208 of
As illustrated in
y=Hx+w, (1)
where xΔ[x1, x2, . . . , xL
A Kronecker model can model several typically encountered channels. See, e.g., J. P. Kermoal et al., A Stochastic MIMO Radio Channel Model with Experimental Validation, IEEE J. Select. Areas Commun., vol. 20, pp. 1211-1226, August 2002; and D. Asztely, On Antenna Arrays in Mobile Communication Systems: Fast Fading and GSM Base Station Receiver Algorithms, Tech. Rep. IR-S3-SB-9611, Royal Institute of Technology, March 1996, the contents of each of which are incorporated herein by reference. The forward channel matrix {tilde over (H)} can be written as
{tilde over (H)}=R
r
1/2
{tilde over (H)}
w
{tilde over (R)}
t
1/2, (2)
where {tilde over (R)}t is a Nt×Nt transmit-side correlation matrix, Rr is a Nr×Nr receive-side correlation matrix, and {tilde over (H)}w is an Nr×Nt spatially white zero-mean unit variance complex i.i.d. Gaussian noise matrix. Therefore, the channel state information (H) between the selected transmit antennas and the receive antennas is given by H=Rr1/2HwRt1/2, where Rt is an Lt×Lt principal submatrix of the matrix {tilde over (R)}t with the rows and columns of the matrix H corresponding to the selected transmit antennas, and Hw is the corresponding Nr×Lt sub-matrix of {tilde over (H)}w.
For a uniform linear array (ULA) with a Gaussian angular distribution, the (i,j)th element, rij, of the correlation matrix, {tilde over (R)}t (or Rr), can be calculated according to D. Asztely, On Antenna Arrays in Mobile Communication Systems: Fast Fading and GSM Base Station Receiver Algorithms, Tech. Rep. IR-S3-Sb-9611, Royal Institute of Technology, March 1996, using the following equation:
where j=√{square root over (−1)}, θ0 is the angle of departure (AoD) or AoA), σθ is the angular spread, and Δ is the wavelength-normalized antenna spacing. The approximation above holds for small σθ and predicts the correct trends for large σ74. The correlation matrix for a uniform circular array (UCA) with a Laplacian distributed AoD (or AoA) is derived in J. -A. Tsai, R. M. Buehrer, and B. D. Woerner, Spatial Fading Correlation Function of Circular Antenna Arrays with Laplacian Energy Distribution, IEEE Commun. Lett., vol. 6, pp. 178-180, May 2002, the contents of which are herein incorporated by reference.
For transmit antenna selection, when Lt out of Nt antennas are to be selected, the total number of selections is
. Let each selection be denoted by the vector, si, which lists the indexes of the Lt transmit antennas selected. Therefore, sl=└sl1,sl2, . . . ,slL
where ┌.┐ is the ceiling function. For the purposes of the following non-limiting explanation, one antenna is assumed to be selected for transmission (e.g., Lt=1). For simplicity, Nt is taken to be a power of two, so that the total number of possible bit sequences and the number of antennas is the same, (i.e., n=log2 Nt is an integer). Therefore, there exists a bijective mapping μ:S→C, called the signaling assignment, such that for all c ε C, there exists an s ε S such that c=μ(s), and μ(s1)≠μ(s2) if (s1)≠(s2).
While it is possible that 2n-Nt bit sequences may exist that are not codewords if Nt is not a power of two, the present invention assumes (as a non-limiting example) that these sequences are mapped based on a pre-specified rule. Of course, other solutions to feedback error resulting in a codeword being received at the transmitter that is not in the codebook are within the scope of the present invention.
In this non-limiting example, it is assumed that the feedback channel is a binary symmetric channel (BSC) with a crossover probability of ε, where 0<ε<1. Errors in the feedback channel result in the transmitter receiving a bit sequence, c′, that is different from the one sent by the receiver, c. Therefore, c′ is another (different) element of C. Using this notation, transmit antenna selection with erroneous feedback can be described as follows: Let s denote the optimum choice made by the receiver. The receiver signals the codeword c=μ(s), which is received by the transmitter as c′. The transmitter then uses the antenna set s′=μ−1(c′). Given that μ(.) is bijective, it follows that μ−1(c′)≠μ−1(c).
However, all the errors are not equally likely. If the Hamming distance between two bit sequences is d, then the probability of erroneously interpreting these two bit sequences is given by the function
Φ(d)=εd(1−ε)n−d (4)
Thus, different Hamming distances lead to different error probabilities. In the absence of spatial correlation, the average standard error of prediction (SEP) of the data can be independent of the signaling assignment. However, in the presence of correlation, the performance degradation can be reduced if the most probable feedback error patterns cause the transmitter to select antenna(s) that are highly correlated with the transmit antennas selected by the receiver. To verify this intuition, a non-limiting example consisting of Nt=4 and Nr=1 antennas, out of which Lt=1 antenna is used for transmission is illustrated in
In a non-limiting example of the present invention, Monte Carlo simulations were used to obtain the average SEPs of the 24 total possible signaling assignments at different SNRs.
While the ideal selection receiver is difficult to achieve, the methods set forth in step S212 of
According to this non-limiting example, the receiver is assumed to know the complex channel matrix {tilde over (H)}. However, due to the presence of feedback errors, the receiver might not know a priori the actual antennas selected for transmission. One goal of the receiver is to detect the transmission data correctly. For this, the receiver often needs to estimate, as an intermediate step, which antenna was selected by the transmitter. Hereafter, s, s′, and ŝ denote the antennas selected and fed back by the receiver, the antennas actually used by the transmitter, and the antennas assumed by the receiver during data detection, respectively. Their corresponding channel coefficients are denoted by hs, hs′, and hŝ. These correspond to appropriate columns of the complete channel matrix {tilde over (H)}.
A receiver that ignores the possibility of feedback error and assumes that the transmitter used the antennas of s, (e.g., the antennas recommended by the receiver) is called the no-selection verification receiver. This receiver assumes that ŝ=s and uses the channel hs to do detection. On the other hand, if the receiver always knows that the antennas s′ was used by the transmitter, the receiver shall be called the ideal selection verification receiver. Therefore, the receiver assumes ŝ=s′ and correctly uses hs′ to do detection. A receiver that determines ŝ using only the received signal, y, given a priori knowledge of the feedback error rate ε is called a blind optimal selection verification receiver. If additional side information is also available to determine ŝ as described below, then the non-blind selection verification receiver applies. To quantify the efficacy of the selection verification process, two verification-related probabilities are defined as follows:
Antenna selection verification error at transmitter:
Antenna selection verification mismatch probability:
Pver(T) is the probability that the receiver cannot determine which transmit antenna was actually used. Pver(R) is the probability that the transmit antenna estimate of the receiver does not match its initial (optimum) choice. Obviously, Pver(T)=0 for ideal selection verification, and Pver(R)=0 for no-selection verification.
Let ML denote the set of all the bijective mappings between two sets of cardinality L. Then, the optimal signaling assignment, μ*, for a given SNR, γ, is given as:
where Pe(μ; γ) denotes the average symbol error probability (SEP) for the signaling assignment μ at SNR γ. Arguably, while the optimal assignment μ* can depend on the operating γ, the results in
In the following non-limiting example, only Lt=1 transmit antenna is selected from the Nt antennas. In this case, the optimal choice of transmit antenna is
where hj denotes the jth column of the matrix {tilde over (H)}. The decision statistic used by the receiver, given that it uses Ŝ as its estimate of the antenna used for transmission and knows {tilde over (H)}, is
ŷ=h
ŝ
†
h
s′
x+h
ŝ
†
w. (9)
The output of the detector is denoted by {circumflex over (x)}.
The average symbol error probability for a given signaling assignment, μ, is given by
The probability Pr(ŝ|s′, s) depends on the selection verification algorithm used at the receiver. For ideal selection verification, we have Pr(ŝ=s′|s′,s)=1; while for no-selection verification, only Pr(s|s′, s)=1. Therefore, in these two cases, in which ŝ is a deterministic function of s and s′, (10) can be simplified to:
The term Pr(s′|s) depends on the feedback error rate E and the signaling assignment μ because
Pr(s′|s)=Φ(d(c′, c))=εd(c′)(1−ε)(n−d(c′,c)), (12)
where c′=μ(s′), c=μ(s), and d(c, c′) denotes the Hamming distance between the two codewords c and c′. Pr(s) is the probability that s is the optimal transmit antenna. In the presence of spatial correlation, it is not the same for all s. However, for moderate spatial correlations, the difference between these probabilities is minor enough to justify the approximation Pr(s)≈1/L. Substituting this approximation into (11) and given that only one antenna is used for transmission yields the following expression for Pe(μ;γ):
The average SEP given s and s′, Ex|s,s′[Pr({circumflex over (x)}≠x| s,s′)], depends on the modulation constellation, the receiver, and the channel statistics. In the presence of spatial correlation and antenna selection, the combination of spatial correlation and order statistics makes it difficult to derive general closed-form expressions for the above expectation. Evaluating it equation 13 numerically or using Monte Carlo simulations makes it infeasible for optimization purposes. We therefore develop very simple approximations that are based only on the second-order statistics of the channel. These are sufficiently accurate for the purposes of optimization. In the following, we develop suitable approximations for Ex|s,s′[Pr({circumflex over (x)}≠x|s,s′)] for ideal selection verification and no-selection verification.
With ideal antenna selection verification, we have ŝ=s′. Therefore, the decision statistic becomes
ŷ=∥h
s′∥2x+hs′†w, (14)
When QPSK modulation is used, the SEP, given hs′, approximately equals 2Q(√{square root over (γ∥hs′∥s/2)}). Therefore,
In (16), the expectation operator is interchanged with the Q function. From Jensen's inequality, the resulting expression is a lower bound on the average SEP.
From the spatial correlation model defined in (2), the correlation between hs′ and hs is rss′. Then, hs′ can be written in terms of hs as hŝ=rss′hs+√{square root over (1−|rss′|2)}n. The vector n is independent of hŝ and hs, and each of its elements is a zero-mean unit-variance complex Gaussian RV. Therefore, Eh
In (17), Q(a)≈exp(−a2/2) for a>0. The term βver(γ) in (18) denotes
as Eh
Because the signal x is QPSK modulated and the constellation symbols are equi-probable, we have Ex|s.s′[Pr({circumflex over (x)}≠x|s,s′]=Pr({circumflex over (x)}≠xs, s′). Substituting the expressions for Pr({circumflex over (x)}≠x|s,s′) in (18) and for Φ( ) in (4) in (11), we get:
Therefore, we can define the metric, Mver(μ; γ), for ideal selection verification as
The common term
which does not depend on μ, is dropped in (20).
A receiver without antenna selection verification uses ŝ=s. Therefore, the decision statistic in this receiver is
ŷ=h
s
†
h
s′
x+h
s
†
w. (21)
As a result, when the signal x is QPSK modulated, we have
where φ is the phase of the complex number hs†hs′. It is a zero-mean RV, and its variance decreases as the spatial correlation increases. For small φ, we have |sin(φ)|<<|cos(φ)|. This justifies the following approximation:
Similarly, sin
As before, the spatial correlation between hs and hs′implies that
h
s′
=r
ss′
h
s+√{square root over (1−|rss′|2)}n,
|hs†hs′|cos(φ)=∥hs∥sRe{√{square root over (1−|rss′|2)}hs†n}, (23)
where n is a zero-mean AWCGN and is independent of hs and hs′. Therefore,
Then Pr({circumflex over (x)}≠x|s,s′) can be approximated by
The first step of the approximation swaps the expectation operator and the Q function. From Jensen's inequality, the resulting expression is a lower bound on the average SEP. This step also uses the fact that
because n is a zero-mean RV that is independent of hs. In (25), βno-ver(γ) denotes
which is independent of μ. Note that it is preferred not to use the approximation, Q(a)≈exp(−a2/2), because Re {rss′} can be negative.
Upon substituting (25) and (4) in (13), we get the following approximation for Pe(μ; γ):
Therefore, we can define the metric Mno-ver(μ; γ) for no-selection verification as:
The common term,
which is independent of μ, is dropped in the above definition.
a) is a scatter plot of the simulated Pe(γ, μ) and the metric Mver(μ; γ), defined in (20), for ideal selection verification and y=6 dB. A total of 800 different assignments for Nt=8 and Nr=1 with Lt=1 are plotted. A total of 40320 assignments are possible. The SNR dependent term, βver(γ), is set to unity.
The strong monotonic relationship between the metric and the average SEP is evident from the plot. So long as this monotonic relationship holds, the metric can be used to compare the various signaling assignments and find the optimal one. On account of the approximations made in the derivation of the metric Mver(μ; γ), the plot displays some scatter. This scatter implies that for a given value of the metric, some uncertainty exists about the exact SEP value. However, it should be noted that the primary region of interest for optimization purposes is the one with lower values of both Pe(μ; γ) and Mver(μ; γ).
b) is a scatter plot of the average SEP from simulations and the metric Mno-ver(μ; γ), defined in (27), for no-selection verification. As before, Mno-ver(γ) is set to unity. The monotonic relationship again holds.
To verify the validity of these approximations, brute force simulations were done for several systems with different number of antennas and spatial correlations. In each case, the plot of the average SEP displayed the desired monotonic relationship with the metrics for both ideal selection verification and no-selection verification. The monotonic relationship holds regardless of the value of βver(γ) and βno-ver(γ). Therefore, these approximations were set to 1 for the following non-limiting explanation of the present invention.
The metrics defined in (20) and (27) depend on system parameters such as the feedback bit error rate, E and the transmit correlation {tilde over (R)}t. The following non-limiting embodiment and description of the present invention relates to the robustness of the optimal signaling assignment to changes in these system parameters.
Lemma 1: For small feedback bit error probabilities, ε<<1, the optimal signaling assignments, μver* and μno-ver*, are independent of ε.
Proof: Let Ŝs(μ) denote the set of all transmit antenna indices whose codewords are 1 bit apart from the codeword μ(s). Hence, Ŝs(μ)Δ{s′|s′εS and d(μ(s′),μ(s))=1}. When ε<<1, single bit errors are most likely. Therefore, the metrics simplify to:
where limε→0 o(ε)/ε=0. Therefore, for ε<<1, the metrics depend on E only through the common term ε/(1−ε), which implies that the optimal signaling assignments are independent of ε, as described in K. Zeger and A. Gersho, Pseudo-Gray Coding, IEEE Trans. Commun., vol. 38, pp. 2147-2158, November 1990, the contents of which are herein incorporated by reference.
For ideal selection verification, the absolute value of the complex spatial correlation coefficient matters, and not its phase. While a different angle spread and a different mean AoD changes the value of the correlation, it follows from (3) that antenna spatially farther apart have a smaller absolute value of correlation than antennas that are closer. Therefore, the optimal signaling assignment derived for one set of parameters will perform well even under a different set of parameters.
The analysis of the previous non-limiting example results in metrics that depend only on the second-order statistics of the channel. The problem at hand is to find the signaling assignment that minimizes the metrics defined in (20) and (27) for ideal selection verification and no-selection verification, respectively.
If there are L codewords, then the total number of signaling assignments is L!. Given a signaling assignment, swapping the Os and is in its codewords leads to another signaling assignment with exactly the same performance, because the feedback channel is a BSC. Therefore, the search space can be reduced to L!/2. Therefore, the complexity of the search for the optimal signaling assignment μ* is very high even for moderate values of Nt and Lt.
The Binary Switching Algorithm (BSA) searches to find a locally optimal signaling assignment in the set of all assignments ML. If only one transmit antenna is chosen from Nt antennas, then the number of possible selections of transmit antennas is L=Nt. To run BSA, it is useful to define the cost function for each choice; the total cost is the sum of the costs of all choices. In the present non-limiting example, the total cost is defined as M(μ; γ), where M(μ;γ)ΔMno-ver(μ;γ) for no-selection verification and M(μ;γ)ΔMver(μ;γ) for ideal selection verification. Correspondingly, the cost for each selection, s ε S is defined as:
for ideal selection verification, and
for no-selection verification. Clearly,
Generally, the steps of BSA are as follows: 1) Randomly select the initial signaling assignment, μ. 2) Calculate the cost function, {circumflex over (M)}s(μ;γ), for each selection s ε S, and the total cost M(μ; γ). 3) Sort the elements in the set {{circumflex over (M)}s(μ;γ)|s ε S} in increasing order. 4) Switch the selection with the highest cost with every other selection. Each switch changes μ to a different signaling assignment, say, μ′. For each switch, calculate the new total cost M(μ′;γ). 5) Pick the switch with the lowest total cost. If it is lower than the initial total cost, save the corresponding signaling assignment, and return to step 2. If it is higher than the initial total cost, then proceed to 6. 6) Switch the selection with the second highest cost with every other choice, and calculate the total cost for each switch. 7) Pick the switch with lowest total cost. If this total cost is lower than the initial cost, save the corresponding signaling assignment, and return to 2. Else, if the total cost is higher than the initial total cost, stop.
The metrics described herein enable a general formulation based on a combinatorial optimization problem known as the quadratic assignment problem. See, P. M. Pardalos, F. Rendl, and H. Wolkowicz, The Quadratic Assignment Problem: A Survey of Recent Developments in Quadratic Assignment and Related Problems, P. Pardalos and H. Wolkowicz, eds., vol. 16, pp 1-42, DIMACS Series in Discrete Mathematics and Theoretical Computer Science (1994), the entire contents of which are herein incorporated by reference. The QAP attempts to find the permutation which minimizes a cost function of the form
where ML is the set of all possible permutations of the set Z={1,2, . . . , L}. As we saw, different permutations correspond to different signaling assignments. In one non fij=exp(−β(γ)|rij|2)-limiting example of the present invention, L=Nt, and the function fij is given by for perfect selection verification and by fij=Q(β(γ) Re(rij)) for no-selection verification. The function gμ(i)μ(j) is given by
and μ(i) and μ(j) are the codewords assigned to transmit antenna indices i and j, respectively. Therefore, efficient algorithms, such as Tebu search, developed for QAP can now be applied to the present invention.
The BSA is guaranteed to stop, and it converges to a locally optimum signaling assignment in many cases. To find the global optimum, the process is started with several different initial signaling assignments, and the assignment with the lowest total cost is selected. The complexity of BSA is of the order of Nt3. The complexity can be reduced to Nt2 log2 (Nt) for ε<<1, when only single feedback bit errors are very likely.
The results of
It is also possible to develop processes that are tailored to the knowledge available at the receiver. These fall into two categories: blind antenna selection verification, in which there is no additional side information available at the receiver, and non-blind antenna selection verification, in which additional side information is available.
A blind antenna selection verification receiver detects the transmitted symbol as well as the antenna used to transmit it from the received data only. In addition, the receiver also has access to the a priori information of which antenna it asked the transmitter to use. Therefore, the following detection rule minimizes the SEP:
where the last step follows because all candidates of x are equi-probable and are independent of s and {tilde over (H)}. The previous equation can be simplified as:
Equation (33) follows from (32) because the feedback errors are independent of the forward link channel state. In (34), it is notable that given hs′, y is independent of s and {tilde over (H)}. The receiver based on (34) is referred to as the blind optimal symbol-level selection verification receiver. Note that it considers all the possible choices of transmit antennas, and does not determine s′ as an intermediate step. Therefore, the verification-related probabilities Pver(T) and Pver(R), defined in (5) and (6), respectively, are not applicable here.
The term p(y|x, hs′) in (34) is an exponential term as it is a Gaussian pdf. By using the approximation log
(34) can be further simplified to:
where ŝ is transmit antenna assumed by the receiver for data estimation. Because the noise is assumed to have unit variance, the term μy−hs′x∥2 is not multiplied with any scaling factor. The receiver based on (35) shall be called the blind sub-optimal symbol-level selection verification receiver. While (35) is a sub-optimal approximation to (34), it will later be evident that the performance penalty is extremely negligible. Moreover, taking the logarithm avoids numerical overflow and underflow problems in evaluating equation 34. For the purposes of the discussion below, the two equations are not distinguished.
The number of possibilities to be considered by the antenna verification receiver in (34) and (35) is 4Nt because the QPSK constellation consists of 4 symbols and the number of possible choices of transmit antennas is Nt. For ε<<1 this complexity can be reduced by only searching over the most probable set of s′. This set corresponds to antennas with codewords that differ from the codeword(s) by only 1 bit. The number of possibilities then reduces to 4┌log2Nt┐.
The selection verification algorithm above is optimal only if the channel changes from one symbol transmission to another. If the channel is block-fading and remains constant over at least K>1 transmissions, then the antenna selection verification performance can be improved by doing it on a block-by-block basis. The optimal receiver now detects the sequence {{circumflex over (x)}1,{circumflex over (x)}2, . . . ,{circumflex over (x)}K} as follows:
As before, (36) can be approximated by:
The optimal and sub-optimal receivers based on (36)) and (37), are referred to respectively, as blind block-level selection verification receivers. While block-level selection verification outperforms symbol-level selection verification, the complexity of the verification increases exponentially with the block fading length as the number of possibilities is of the order of 4KNt. Therefore, block-level selection verification quickly become impractical even for moderate K.
While optimal blind selection verification overcomes the catastrophic error floor limitation of no-selection verification, it is evident that there is still a large performance gap compared to ideal selection verification. In fact, the SEP performance is now limited largely by Pver(T). Therefore, additional side information is desirable to further reduce the selection verification error. Additional side information can be incorporated into the system by making the transmitter transmit from the selected antenna a short pilot symbol sequence before the data.
Let the antenna be selected once every K symbols, where K is smaller than the block fading duration. Transmission using the selected antenna occurs in two phases: first Kp symbols are used for the pilot; then the remaining Kd=K−Kp symbols are used for data. We also assume that the transmit power can be varied during the two phases. A fraction a of the total energy is allocated to the pilot symbols and the remaining energy is allocated to data symbols.
In a training phase, the transmitter sends a 1 x Kp pilot symbol vector xp. The receiver receives:
Y
p
=h
s′
x
p
+W
p, (38)
where Wp is the Nr x Kp zero-mean unit-variance AWCGN. Since xp is known by the receiver, the optimal rule for ŝ is as follows:
Here, (40) follows from Baye's rule and Pr(s′|s,{tilde over (H)},xp)=Pr(s′|s) because the errors on the feedback channel are independent of the forward channel, {tilde over (H)}, and xp. Equation (41) follows because p(Yp|xp,s,s′,{tilde over (H)})=P(Yp|xp,hs′).
After the receiver estimates ŝ, the receiver uses hŝ to detect the transmitted data. Keeping in mind the complexity of blind selection verification, it is assumed that the receiver does not use the data signals to refine its selection estimate, ŝ. The receiver based on (41) is referred to as the non-blind optimal selection verification receiver.
In the numerical results that follow, the error rate of the feedback channel is ε=0.04. A ULA is considered with a wavelength-normalized spacing of Δ=0.5. The angular spread is σθ=30° and the mean AoD is θ0=30° in (3).
Table I(a) (illustrated in
a) compares the SEP performance of μver* and μno-ver*. It can be seen that no-selection verification exhibits an error floor that is of the order of nε, while the ideal selection verification does not suffer from such a floor. Optimal signaling assignments lead to a lower error floor for no-selection verification and a 1.5 to 2 dB improvement in SNR for ideal selection verification.
It is interesting to note that the signaling assignment, μver*, optimized for ideal selection verification, performs poorly when used with no-selection verification. The same conclusion also applies to the case when μno-ver*, which is optimized for no-selection verification, is used with ideal selection verification.
For Nt=16 and Lt=1, the total number of signaling assignments increases to 16!=2.0923e+013, which is well beyond the brute-force search capabilities of many computers. For Nt=16 the BSA was run for 100 randomly chosen initial signaling assignments. Table I(b) lists the best signaling assignments, along with two randomly chosen ones, for Nt=16.
a) compares the SEP performance of the blind optimal symbol-level selection verification receiver (line) and the blind sub-optimal symbol-level selection verification receiver (dot) for the two signaling assignments μver* and μno-ver*. It can be seen that there is no difference in SEP performance for these two receivers. For blind symbol-level selection verification, μno-ver* works better at low SNR, while μver* works better at high SNR.
To clarify blind symbol-level selection verification,
Previous figures showed that blind selection verification, even if optimal, has decreased performance compared to ideal selection verification. Side information is one way of improving performance.
As a non-limiting alternative, more symbols or more energy can be allocated to the pilot to improve the selection verification accuracy. However, increasing the number of pilot symbols reduces the transmission time for data and reduces the net transmission rate. Equivalently, for a fixed total energy budget and a fixed number of pilot symbols, increasing the energy allocated to pilots reduces the energy available for data transmission and increases the SEP.
The previous examples considered the case where the number of possible bit sequences equals the number of available transmit antenna sets. The following non-limiting examples consider the coded feedback case, where more bit sequences than the required number of codewords are available.
In the following non-limiting example, more bit sequences are available than the required number of codewords. The first case is one in which the bit sequences are codewords of length n bits of an error correction code as described in J. G. Proakis, Digital Communications, McGraw-Hill, 2nd ed., 1989, S. Lin and D. J. Costello, Error Control Coding, Prentice Hall, 2 ed., 2004, the contents of which are herein incorporated by reference. In this case, the invention described herein can be applied as follows. The codeword error probability formula, Φ, changes from the one given in (4) to the corresponding codeword error probability for the error correction code being used. Therefore, formulae for the metrics in (20) and (27) will use the code-specific formula for Φ. The formulae for selection verification in (34), (35), (36), (37), and (41) will also use the code-specific formula for Φ. Given that it is difficult to determine this probability, in closed-form, for many codes, approximations such as the union bound approximation may also be used as described by J. G. Proakis, Digital Communications, McGraw-Hill, 2nd ed., 1989, S. Lin and D. J. Costello, Error Control Coding, Prentice Hall, 2 ed., 2004.
The most general formulation of the problem is the following. Let L denote the cardinality of S, which is the total number of transmit antenna choices. Let the feedback codewords use n bits. Therefore, the total number of possible bit sequences is 2n, of which L are codewords. The signaling assignment problem then needs to determine the L bit sequences, out of the possible 2n bit sequences, that will be used as codewords, and also determine the signaling assignment between the codewords and the transmit antenna choices. Therefore, the total number of possibilities is (2LN)L!.
We now describe a virtual antenna technique to determine the optimal signaling assignment. Let L=2k. For each transmit antenna choice, we first create 2n−k virtual antennas. All these 2n−k virtual antennas are co-located at the location of the “real” transmit antenna choice. There are now 2n, virtual antenna selections.
The optimization can be done in two steps. In the first step, 2n×2n virtual correlation matrix is created,
where {circle around (X)} is the Kronecker product, and 12n−k is an all-one matrix of size 2n−k×2n−k. The correlation between two virtual choices is just the corresponding element in the virtual correlation matrix,
With this correlation matrix, the metrics and BSA described above can be applied to find optimal signaling assignment from the virtual antenna set to the set of all bit sequences. This step results in 2n−k bit sequences being assigned to each “real” transmit antenna choice.
The second step of optimization determines, for each real transmit antenna choice, which codeword from the from the 2n−k bit sequences is to be used for feedback. This can be done either by choosing them randomly or by means of a brute-force search over the 2n−k codewords.
The present invention includes processing of transmitted and received signals, and programs by which the received signals are processed. Such programs are typically stored and executed by a processor in a wireless receiver implemented in VLSI. The processor typically includes a computer program product for holding instructions programmed and for containing data structures, tables, records, or other data. Examples are computer readable media such as compact discs, hard disks, floppy disks, tape, magneto-optical disks, PROMs (EPROM, EEPROM, flash EPROM), DRAM, SRAM, SDRAM, or any other magnetic medium, or any other medium from which a processor can read.
The computer program product of the invention may include one or a combination of computer readable media to store software employing computer code devices for controlling the processor. The computer code devices may be any interpretable or executable code mechanism, including but not limited to scripts, interpretable programs, dynamic link libraries (DLLs), Java classes, and complete executable programs. Moreover, parts of the processing may be distributed for better performance, reliability, and/or cost.
While the invention has been described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments in any way and that the invention is intended to cover all the various modifications and equivalent steps which one of ordinary skill in the art would appreciate upon reading this specification.
Numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US05/29746 | 8/19/2005 | WO | 00 | 2/19/2008 |