This invention relates to wireless communication and, more particularly, to techniques for effective wireless communication in the presence of fading and other degradations.
The most effective technique for mitigating multipath fading in a wireless radio channel is to cancel the effect of fading at the transmitter by controlling the transmitter's power. That is, if the channel conditions are known at the transmitter (on one side of the link), then the transmitter can pre-distort the signal to overcome the effect of the channel at the receiver (on the other side). However, there are two fundamental problems with this approach. The first problem is the transmitter's dynamic range. For the transmitter to overcome an x dB fade, it must increase its power by x dB which, in most cases, is not practical because of radiation power limitations, and the size and cost of amplifiers. The second problem is that the transmitter does not have any knowledge of the channel as seen by the receiver (except for time division duplex systems, where the transmitter receives power from a known other transmitter over the same channel). Therefore, if one wants to control a transmitter based on channel characteristics, channel information has to be sent from the receiver to the transmitter, which results in throughput degradation and added complexity to both the transmitter and the receiver.
Other effective techniques are time and frequency diversity. Using time interleaving together with coding can provide diversity improvement. The same holds for frequency hopping and spread spectrum. However, time interleaving results in unnecessarily large delays when the channel is slowly varying. Equivalently, frequency diversity techniques are ineffective when the coherence bandwidth of the channel is large (small delay spread).
It is well known that in most scattering environments antenna diversity is the most practical and effective technique for reducing the effect of multipath fading. The classical approach to antenna diversity is to use multiple antennas at the receiver and perform combining (or selection) to improve the quality of the received signal.
The major problem with using the receiver diversity approach in current wireless communication systems, such as IS-136 and GSM, is the cost, size and power consumption constraints of the receivers. For obvious reasons, small size, weight and cost are paramount. The addition of multiple antennas and RF chains (or selection and switching circuits) in receivers is presently not feasible. As a result, diversity techniques have often been applied only to improve the up-link (receiver to base) transmission quality with multiple antennas (and receivers) at the base station. Since a base station often serves thousands of receivers, it is more economical to add equipment to base stations rather than the receivers.
Recently, some interesting approaches for transmitter diversity have been suggested. A delay diversity scheme was proposed by A. Wittneben in “Base Station Modulation Diversity for Digital SIMULCAST,” Proceedings of the 1991 IEEE Vehicular Technology Conference (VTC 41 st), pp. 848-853, May 1991, and in “A New Bandwidth Efficient Transmit Antenna Modulation Diversity Scheme For Linear Digital Modulation,” in Proceedings of the 1993 IEEE International Conference on Communications (IICC '93), pp. 1630-1634, May 1993. The proposal is for a base station to transmit a sequence of symbols through one antenna, and the same sequence of symbols—but delayed—through another antenna.
U.S. Pat. No. 5,479,448, issued to Nambirajan Seshadri on Dec. 26, 1995, discloses a similar arrangement where a sequence of codes is transmitted through two antennas. The sequence of codes is routed through a cycling switch that directs each code to the various antennas, in succession. Since copies of the same symbol are transmitted through multiple antennas at different times, both space and time diversity are achieved. A maximum likelihood sequence estimator (MLSE) or a minimum mean squared error (MMSE) equalizer is then used to resolve multipath distortion and provide diversity gain. See also N. Seshadri, J. H. Winters, “Two Signaling Schemes for Improving the Error Performance of FDD Transmission Systems Using Transmitter Antenna Diversity,” Proceedings of the 1993 IEEE Vehicular Technology Conference (VTC 43rd), pp. 508-511, May 1993; and J. H. Winters, “The Diversity Gain of Transmit Diversity in Wireless Systems with Rayleigh Fading,” Proceedings of the 1994 ICC/SUPERCOMM, New Orleans, Vol. 2, pp. 1121-1125, May 1994.
Still another interesting approach is disclosed by Tarokh, Seshadri, Calderbank and Naguib in U.S. application Ser. No. 08/847,635, filed Apr. 25, 1997 (based on a provisional application filed Nov. 7, 1996), where symbols are encoded according to the antennas through which they are simultaneously transmitted, and are decoded using a maximum likelihood decoder. More specifically, the process at the transmitter handles the information in blocks of M1 bits, where M1 is a multiple of M2, i.e., M1=k*M2. It converts each successive group of M2 bits into information symbols (generating thereby k information symbols), encodes each sequence of k information symbols into n channel codes (developing thereby a group of n channel codes for each sequence of k information symbols), and applies each code of a group of codes to a different antenna.
The problems of prior art systems are overcome, and an advance in the art is realized with a simple block coding arrangement where symbols are transmitted over a plurality of transmit channels and the coding comprises only simple arithmetic operations, such as negation and conjugation. The diversity created by the transmitter utilizes space diversity and either time diversity or frequency diversity. Space diversity is effected by redundantly transmitting over a plurality of antennas; time diversity is effected by redundantly transmitting at different times; and frequency diversity is effected by redundantly transmitting at different frequencies. Illustratively, using two transmit antennas and a single receive antenna, one of the disclosed embodiments provides the same diversity gain as the maximal-ratio receiver combining (MRRC) scheme with one transmit antenna and two receive antennas. The novel approach does not require any bandwidth expansion or feedback from the receiver to the transmitter, and has the same decoding complexity as the MRRC. The diversity improvement is equal to applying maximal-ratio receiver combining (MRRC) at the receiver with the same number of antennas. The principles of this invention are applicable to arrangements with more than two antennas, and an illustrative embodiment is disclosed using the same space block code with two transmit and two receive antennas. This scheme provides the same diversity gain as four-branch MRRC.
In accordance with the principles of this invention, effective communication is achieved with encoding of symbols that comprises merely negations and conjugations of symbols (which really is merely negation of the imaginary part) in combination with a transmitter created diversity. Space diversity and either frequency diversity or time diversity are employed.
At any given time, a signal sent by a transmitter antenna experiences interference effects of the traversed channel, which consists of the transmit chain, the air-link, and the receive chain. The channel may be modeled by a complex multiplicative distortion factor composed of a magnitude response and a phase response. In the exposition that follows therefore, the channel transfer function from transmit antenna 11 to receive antenna 21 is denoted by h0, and from transmit antenna 12 to receive antenna 21 is denoted by h1 where:
h
0=α0ejθ
h
1=α1ejθ
Noise from interference and other sources is added at the two received signals and, therefore, the resulting baseband signal received at any time and outputted by reception and amplification section 25 is
r(t)=α0ejθ
where si and sj are the signals being sent by transmit antenna 11 and 12, respectively.
As indicated above, in the two-antenna embodiment of
r(t)=h0si+h1sj+n(t), (3)
and in the next time interval the received signal is
r(t+T)=−h0sj*+h1si*+n(t+T). (4)
Table 1 illustrates the transmission pattern over the two antennas of the
The received signal is applied to channel estimator 22, which provides signals representing the channel characteristics or, rather, the best estimates thereof. Those signals are applied to combiner 23 and to maximum likelihood detector 24. The estimates developed by channel estimator 22 can be obtained by sending a known training signal that channel estimator 22 recovers, and based on the recovered signal the channel estimates are computed. This is a well known approach.
Combiner 23 receives the signal in the first time interval, buffers it, receives the signal in the next time interval, and combines the two received signals to develop signals
{tilde over (s)}
i
={tilde over (h)}
0
*r(t)+{tilde over (h)}1r*(t+T)
{tilde over (s)}
j
={tilde over (h)}
1
*r(t)−{tilde over (h)}0r*(t+T) (5)
Substituting equation (1) into (5) yields
{tilde over (s)}
i=({tilde over (α)}02+{tilde over (α)}12)si+{tilde over (h)}0*n(t)+{tilde over (h)}1n*(t+T)
{tilde over (s)}
j=({tilde over (α)}02+{tilde over (α)}12)sj+{tilde over (h)}0n*(t+T)+{tilde over (h)}1n*(t+T) (6)
where {tilde over (α)}02={tilde over (h)}0{tilde over (h)}0* and {tilde over (α)}12={tilde over (h)}1{tilde over (h)}1*, demonstrating that the signals of equation (6) are, indeed, estimates of the transmitted signals (within a multiplicative factor). Accordingly, the signals of equation (6) are sent to maximum likelihood detector 24.
In attempting to recover si, two kinds of signals are considered: the signals actually received at time t and t+T, and the signals that should have been received if si were the signal that was sent. As demonstrated below, no assumption is made regarding the value of sj. That is, a decision is made that si=sx for that value of x for which
d
2
[r(t),(h0sx+h1sj)]+d2[r(t+T),(−h1sj*+h0sx*)]
is less than
d
2
[r(t),(h0sk+h1sj)]+d2[r(t+T),(−h1sj*+h0sk*)] (7)
where d2 (x,y) is the squared Euclidean distance between signals x and y, i.e., d2(x,y)=|x−y|2.
Recognizing that {tilde over (h)}0=h0+noise that is independent of the transmitted symbol, and that {tilde over (h)}1=h1+noise that is independent of the transmitted symbol, equation (7) can be rewritten to yield
(α02+α12)|sx|2−{tilde over (s)}isx*−{tilde over (s)}i*sx≦(α02+α12)|sk|2−{tilde over (s)}isk*−{tilde over (s)}i*sk (8)
where α02=h0h0* and α12=h1h1*; or equivalently
(α02+α12−1)|sx|2+d2({tilde over (s)}i,sx)≦(α02+α12−1)|sk|2+d2({tilde over (s)}i,sk) (9)
In Phase Shift Keying modulation, all symbols carry the same energy, which means that |sx|2=|sk|2 and, therefore, the decision rule of equation (9) may be simplified to choose signal
{tilde over (s)}
i
=s
x
iff d
2({tilde over (s)}i,sx)≦d2({tilde over (s)}i,sk). (10)
Thus, maximum likelihood detector 24 develops the signals sk for all values of k, with the aid of {tilde over (h)}0 and {tilde over (h)}1 from estimator 22, develops the distances d2 {tilde over (s)}i, sk), identifies x for which equation (10) holds and concludes that {tilde over (s)}i=sx. A similar process is applied for recovering {tilde over (s)}j.
In the above-described embodiment each block of symbols is recovered as a block with the aid of channel estimates {tilde over (h)}0 and {tilde over (h)}1. However, other approaches to recovering the transmitted signals can also be employed. Indeed, an embodiment for recovering the transmitted symbols exists where the channel transfer functions need not be estimated at all, provided an initial pair of transmitted signals is known to the receiver (for example, when the initial pair of transmitted signals is prearranged). Such an embodiment is shown in
r
0
=r(t)=h0s0+h1s1+n0
r
1
=r(t+T)=h1s0*−h0s1*+n1
r
2
=r(t+2T)=h0s2+h1s3+n2
r
3
=r(t+3T)=h1s2*−h0s3*+n3, (11)
then develops intermediate signals A and B
A=r
0
r
3
*−r
2
r
1*
B=r
2
r
0
*−r
1
r
3*, (12)
and finally develops signals
{tilde over (s)}
2
=As
1
*+Bs
0
{tilde over (s)}
3
=As
0
*+Bs
1, (13)
where N3 and N4 are noise terms. It may be noted that signal r2 is actually r2=h0ŝ2+h1ŝ3=h0s2+h1s3+n2, and similarly for signal r3. Since the makeup of signals A and B makes them also equal to
A=(α02+α12)(s2S1−s3s0)+N1
B=(α02+α12)(s2s0*+s3S1*)+N2, (14)
where N1 and N2 are noise terms, it follows that signals {tilde over (s)}2 and {tilde over (s)}3 are equal to
{tilde over (s)}
2=(α02+α12)(|s0|2+|s1|2)s2+N3
{tilde over (s)}
3=(α02+α12)(|s0|2+|s1|2)s3+N4. (15)
When the power of all signals is constant (and normalized to 1) equation (15) reduces to
{tilde over (s)}
2=(α02+α12+N3
{tilde over (s)}
3=(α02+α12)s3+N4. (16)
Hence, signals {tilde over (s)}2 and {tilde over (s)}3 are, indeed, estimates of the signals s2 and s3 (within a multiplicative factor). Line 28 and 29 demonstrate the recursive aspect of equation (13), where signal estimates {tilde over (s)}2 and {tilde over (s)}3 are evaluated with the aid of recovered signals s0 and s1 that are fed back from the output of the maximum likelihood detector.
Signals {tilde over (s)}2 and {tilde over (s)}3 are applied to maximum likelihood detector 24 where recovery is effected with the metric expressed by equation (10) above. As shown in
and applies those estimates to combiner 23 and to detector 42. Detector 24 recovers signals s2 and s3 by employing the approach used by detector 24 of
The
Based on the above, it can be shown that the received signals are
r
0
=h
0
s
0
+h
1
s
1
+n
0
r
1
=−h
0
s
1
*+h
1
s
0
*+n
1
r
2
=h
2
s
0
+h
3
s
1
+n
2
r
3
=−h
2
s
1
*+h
3
s
0
*+n
3 (18)
where n0, n1, n2, and n3 are complex random variables representing receiver thermal noise, interferences, etc.
In the
{tilde over (s)}
0
=h
0
*r
0
+h
1
r
1
*+h
2
*r
2
+h
3
r
3*
{tilde over (s)}
1
=h
1
*r
0
−h
0
r
1
*+h
3
*r
2
−h
2
r
3*. (19)
Substituting the appropriate equations results in
{tilde over (s)}
0=(α02+α12+α22+α32)s0+h0*n0+h1n1*+h2*n2+h3n3*
{tilde over (s)}
1=(α02+α12+α22+α32)s1+h1*n0−h0n1*+h3*n2−h2n3* (20)
which demonstrates that the signal {tilde over (s)}0 and {tilde over (s)}i are indeed estimates of the signals s0 and s1. Accordingly, signals {tilde over (s)}0 and {tilde over (s)}1 are sent to maximum likelihood decoder 56, which uses the decision rule of equation (10) to recover the signals ŝ0 and ŝ1.
As disclosed above, the principles of this invention rely on the transmitter to force a diversity in the signals received by a receiver, and that diversity can be effected in a number of ways. The illustrated embodiments rely on space diversity—effected through a multiplicity of transmitter antennas, and time diversity—effected through use of two time intervals for transmitting the encoded symbols. It should be realized that two different transmission frequencies could be used instead of two time intervals. Such an embodiment would double the transmission speed, but it would also increase the hardware in the receiver, because two different frequencies need to be received and processed simultaneously.
The above illustrated embodiments are, obviously, merely illustrative implementations of the principles of the invention, and various modifications and enhancements can be introduced by artisans without departing from the spirit and scope of this invention, which is embodied in the following claims. For example, all of the disclosed embodiments are illustrated for a space-time diversity choice, but as explained above, one could choose the space-frequency pair. Such a choice would have a direct effect on the construction of the receivers.
This application is a continuation of U.S. application Ser. No. 14/319,428, filed Jun. 30, 2014, which is a continuation of U.S. application Ser. No. 13/740,827, filed Jan. 14, 2013 (now U.S. Pat. No. 8,767,874), which is a division of U.S. application Ser. No. 13/073,369, filed Mar. 28, 2011 (now U.S. Pat. No. 8,355,475), which is a continuation of U.S. application Ser. No. 11/828,790, filed Jul. 26, 2007 (now U.S. Pat. No. 7,916,806), which is a division of U.S. application Ser. No. 11/536,474, filed Sep. 28, 2006 (now U.S. Pat. No. 7,386,077), which is a continuation of U.S. application Ser. No. 10/873,567, filed Jun. 22, 2004 (now U.S. Pat. No. 7,120,200), which is a continuation of U.S. application Ser. No. 09/730,151, filed Dec. 5, 2000 (now U.S. Pat. No. 6,775,329), which is a continuation of U.S. application Ser. No. 09/074,224, filed May 7, 1998 (now U.S. Pat. No. 6,185,258), which claims the benefit of U.S. Provisional Application No. 60/059,016, filed Sep. 16, 1997, U.S. Provisional Application No. 60/059,219, filed Sep. 18, 1997, and U.S. Provisional Application No. 60/063,780, filed Oct. 31, 1997; all of which applications are hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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60059016 | Sep 1997 | US | |
60059219 | Sep 1997 | US | |
60063780 | Oct 1997 | US |
Number | Date | Country | |
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Parent | 13073369 | Mar 2011 | US |
Child | 13740827 | US | |
Parent | 11536474 | Sep 2006 | US |
Child | 11828790 | US |
Number | Date | Country | |
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Parent | 14319428 | Jun 2014 | US |
Child | 14950332 | US | |
Parent | 13740827 | Jan 2013 | US |
Child | 14319428 | US | |
Parent | 11828790 | Jul 2007 | US |
Child | 13073369 | US | |
Parent | 10873567 | Jun 2004 | US |
Child | 11536474 | US | |
Parent | 09730151 | Dec 2000 | US |
Child | 10873567 | US | |
Parent | 09074224 | May 1998 | US |
Child | 09730151 | US |