The present invention relates to channel estimators in wireless communication systems generally and to such channel estimators that operate on data and pilot signals in particular.
In practical digital communication systems, the frequency response of the underlying channel from the transmitter to the receiver is seldom known at the receiver side. For example, in digital communication over the dial-up telephone network, the communication channel will be different every time a number is dialed, because the channel route will be different. In this example, the characteristics of the channel are unknown a priori. There are other types of channels, e.g. wireless channel such as radio channels and underwater acoustic channels, whose frequency response characteristics are time varying. Thus coherent communications for such channels require the utilization of adaptive algorithms, known as “channel estimators”, for tracking/estimating the varying characteristics of the channel.
Traditionally, channel estimators are divided into two categories: data aided and non-data aided (blind) estimators. Data aided channel estimators operate on a pre-specified set of transmitted symbols that are known to the receiver. These symbols do not convey any information and are often called “pilot symbols” or “training sequences”. Data aided channel estimators are typically simple to implement and relatively robust. Their major disadvantage is that they lead to an overall reduction in system throughput, since some of the transmitted symbols (the pilot symbols) do not carry any information.
Non data aided channel estimators, on the other hand, do not reduce the system throughput. However, they are typically quite complicated to implement as they are often based on higher order moments/cumulants of the received signal, and they most often suffer from high statistical variability, i.e. they suffer from large estimation errors.
The article “Maximum A Posteriori Multipath Fading Channel Estimation for CDMA Systems” by Mohamed Siala and Daniel Duponteil, Proceedings of Vehicular Technology Conference, Houston, Tex., May, 1999, describes a channel estimation algorithm which combines both approaches. This algorithm uses both pilot and data symbols to construct a channel estimator. However, this algorithm requires that the joint statistical probability distribution of the channel multipaths be known to the receiver. In practice, a complete statistical description of the channel characteristics is seldom known to the receiver. Moreover, these characteristics may be time varying.
An object of the present invention is to provide an improved channel estimator without using any a priori statistical information about the channel. Instead, the present invention uses a priori probabilities of the received symbols, be they pilot, data, power control, etc. symbols.
There is therefore provided, in accordance with a preferred embodiment of the present invention, a channel estimator based on the values of received data and on a priori probabilities only of received symbols. The channel estimator includes a symbol probability generator, a noise variance estimator and a channel tap estimator. The symbol probability generator generates a priori probabilities only of transmitted symbols found in the received signal(s). The noise variance estimator estimates at least one noise variance corrupting the received signal(s). The channel tap estimator generates channel estimates from the received signal(s), the a priori probabilities and the noise variance(s).
Additionally, in accordance with a preferred embodiment of the present invention, the channel tap estimator solves the following equation:
Moreover, in accordance with a preferred embodiment of the present invention, the channel tap estimator includes a z-unit, a combiner and a channel tap unit. The z-unit generates a z-value for z(t;ĥML) from the a priori probabilities, the noise variance(s) and the channel estimates. The combiner combines the z-value with the received signal(s). The channel tap unit determines channel tap values from the output of the combiner.
Further, in accordance with a preferred embodiment of the present invention, the z-unit calculates the following equation for a quadrature phase shift keying (QPSK) channel:
where
Still further, in accordance with a preferred embodiment of the present invention, the channel tap unit is a summer over a window of received symbols.
Additionally, in accordance with a preferred embodiment of the present invention, when s(t) is a pilot symbol, then
p1(t)=p2(t)=p3(t)=p4(t)=0.25
When s(t) is a transmit power control (IPC) symbols, then
p1(t)=p4(t)=0.5, p2(t)=p3(t)=0
Moreover, in accordance with a preferred embodiment of the present invention, the channel tap unit includes an anchor unit, an averager and an interpolator. The anchor unit determines a pilot anchor ĥp using Np pilot symbols of one time slot n and a data anchor ĥs using Ns data symbols of the time slot n. The averager averages the pilot and data anchors to produce a slot anchor ĥanchor(n) and the interpolator interpolates between adjacent anchors ĥanchor(n−1) and ĥanchor(n) to obtain channel estimates for the n-th slot.
Further, in accordance with a preferred embodiment of the present invention, Ns=2Np and Np of the data symbols can be taken from before the pilot symbols of the time slot and Np of the data symbols can be taken from after the pilot symbols.
Still further, in accordance with a preferred embodiment of the present invention, the unit for linearly interpolates includes unit for separately interpolates amplitudes and phases of the adjacent anchors.
Additionally, in accordance with a preferred embodiment of the present invention, the channel estimator also includes a unit that averages slot anchors as follows:
where Ĥanchor is the average value of slot anchors ĥanchor in a slot ranging between the values −M to M for k, and βk is a user defined weight factor.
Moreover, in accordance with a preferred embodiment of the present invention, the z-unit includes a lookup table unit.
Further, in accordance with a preferred embodiment of the present invention, the at least one received signal is the output of at least one despreader. Alternatively, it could be the downconverted and demodulated output of more than one antenna
Still further, in accordance with a preferred embodiment of the present invention, the noise variance estimator generates a noise variance
{circumflex over (σ)}k2(n)=(1−α)·{circumflex over (σ)}k2(n−1)+α·{tilde over (σ)}k2(n)
where the time index n is in units of slot, α is a user selectable exponential forgetting factor, and
where Np is the number of pilot symbols per slot, G(t) is an automatic gain control (AGC) level and
Further, in accordance with a preferred embodiment of the present invention, the channel tap unit is an infinite impulse response (IIR) filter given by:
where ai and bi are user-defined parameters as are the filter orders p and q.
Alternatively, there is also provided a channel estimator having two estimators, a first estimator that operates on a continuous pilot channel and a second estimator that operates on a traffic channel with interleaved pilot symbols. The estimator also includes a combiner that combines the output of the first and second estimators. The first estimator is similar to those of the prior art while the second estimator is similar to that described hereinabove.
Finally, the present invention includes the methods performed by the channel estimators disclosed herein.
The present invention will be understood and appreciated more fully from the following detailed description taken in conjunction with the appended drawings and Appendix in which:
Appendix A provides a series of approximations to a main component of the channel estimator to simplify its implementation.
The present invention is a channel estimator for linearly modulated, digital communication schemes. It takes as input the downconverted and demodulated received signal, denoted by a vector
The present text will emphasize CDMA cellular systems; however, the present invention can be applied to any digital, linear modulation scheme.
It will be appreciated that, in a receiver having more than one antenna, different elements of the vector
Various embodiments of channel estimator 22 are shown in
Derivation
The vector output
It will be appreciated that:
dim{
where dim{
In accordance with a preferred embodiment of the present invention, the following assumptions are made in order to generate the channel estimator:
The present invention defines a probability vector
For a QPSK symbol constellation,
If s(t) is a pilot symbol, then there exist some i, 1≦i≦4 such that
Furthermore, if there is some a-priori information on the transmitted data, it can be incorporated herein. For example, the transmit power control (IPC) symbols are known a-priori to have only one out of 2 possible values either 1+j or −1−j. For TPC symbols, the corresponding
Now, with the above assumptions, the conditional pdf of
Therefore,
Due to the i.i.d nature of both s(t) and
Now, maximum likelihood (ML) estimation of
The ML channel estimator is obtained by solving the implicit equation:
Using the equality below,
It will be appreciated that, in the general setting, no closed form solution exists to Equation 16. However, there are some special cases of the ML estimator of Equation 16. First, consider the case of pilot symbols, by substituting Equation 3 into Equation 15: This results in:
z(t;
In a high SNR setting, it can be shown that, in both nominator and denominator of z(t;
z(t;
In a low SNR setting, the ML estimator of the present invention, in effect, uses a soft symbol metric that is based on the instantaneous SNR and follows a hyperbolic law. To illustrate this, reference is now made to
As can be seen, at the high SNR of
Until now, the noise variance has been identical for all elements of the noise vector
In some applications, such as the 3GPP wideband CDMA cellular systems, there is a continuous pilot channel separate from a traffic channel that contains data and pilot symbols. For these applications, a channel estimator based on both the traffic and the pilot channels can be constructed. The channel estimator of the present invention can be used for the traffic channel while a prior art channel estimator can be used for the continuous pilot channel. The two channel estimates can be combined to produce the final channel estimate. This provides a statistically more stable channel estimator.
Implementation
Reference is now made to
Noise variance estimator 32 determines the noise variance σ2 as described hereinbelow. There are a variety of methods, known in the art, for estimating the noise variance σ2. One method, incorporated herein by reference, is described in the article “An Efficient Algorithm for Estimating the Signal-to-Interference Ratio in TDMA Cellular Systems”, by Mustafa Turkboylari et al., IEEE Transactions on Communications Vol. 46, No. 6, June 1998, pp. 728-731.
Another method of estimating the noise variance, suitable for the 3GPP wideband CDMA time slot structure, uses pilot symbols, only and implements the following equations for the k-th element of the noise variance vector
{circumflex over (σ)}k2(n)=(1−α)·{circumflex over (σ)}k2(n−1)+α·{tilde over (σ)}k2(n) Equation 25
Where the time index n is in units of slot, α is a user selectable exponential forgetting factor, and
Symbol probability generator 34 receives information from higher layers in the receiver defining the type of the current symbol. For example, the higher layer may indicate that the current symbol is a pilot, a power control or a data symbol. Symbol probability generator 34 then produces the probability vector
Channel tap determiner 36 determines the channel tap estimate vector by solving Equation 16. Since Equation 16 is an implicit equation, one has to resort to iterative algorithms for solving it. There are numerous iterative approaches, based on gradients and/or Hessians of Equation 16 that can be implemented. See, for example, the book Numerical Recipes in C: The Art of Scientific Computing by Press et al., 2nd Edition, Cambridge University Press, 1992.
Channel estimator 30 operates in a “batch” mode, taking a sequence of T samples (where T is a user selectable parameter often related to the fading rate) and iterating until the channel estimate
As with any iterative algorithm, an initial point must be provided for the algorithm. There are a variety of initialization procedures. For example, one may arbitrarily set the initial
Reference is now made to
In the embodiment of
Z-generator 37 receives the demodulated scalar signal y(t), the probability vector
Multiplier 38 multiplies the output y(t) with the value z(t;h′) and summer 39 sums the output of multiplier 38 over a period of length T. The result is the updated channel estimate h which is then fed back to z-generator 37.
Reference is now made to
Channel estimator 40 comprises noise variance estimator 32, a z-generator 42, two multipliers 38A and 38B and two summers 39A and 39B. Z-generator 42 receives the demodulated vector signal
Z-generator 42 then generates the value z(t;h′) from Equation 15. Multipliers 38A and 38B multiply the outputs y0(t)and y1(t), respectively, with the value z(t;h′) and summers 39A and 39B sum the outputs of their respective multipliers 38A and 38B over a period of length T. Each summer 39 produces its updated channel estimate hi, which is also fed back to z-generator 42.
It will be appreciated that the present invention is also operative for more than two taps. The structure of the channel estimator is similar to that of
The channel estimator of the present invention can also be implemented in a sequential (or adaptive) manner. For these implementations, the channel estimator updates the estimate one sample at a time. This amounts to finding a sequential solution to Equation 16 and it typically takes some time to converge. Adaptive solutions inherently assume a slowly time-varying channel so that channel variations can be tracked. Initialization for these implementations is as described hereinabove.
Reference is now made to
Adaptive channel tap determiner 102 sequentially solves Equation 27 (hereinbelow) where, for each new time instance t, a new solution is obtained.
There are a variety of sequential algorithms, two of which are presented hereinbelow.
A first approach uses anchors and linear interpolation between adjacent anchors similar to the one described in the following documents that are incorporated herein by reference:
H. Andoh, M. Sawahashi, and F. Adachi, “Channel Estimation Using Time Multiplexed Pilot Symbols for Coherent Rake Combining for DS-CDMA Mobile Radio,” Proceedings of the IEEE Vehicular Technology Conference, 1997, pp. 954-958.
F. Adachi and M. Sawahashi, “Wideband Wireless Access Based on DS-CDMA,” IEEE Transactions on Communications, pp. 1305-1316, July 1998.
F. Adachi, M. Sawahashi, and H. Suda, “Wideband DS-CDMA for Next Generation Mobile Communications Systems,” IEEE Communications Magazine, September 1998.
In the prior art anchor approach, illustrated in
In accordance with a preferred embodiment of the present invention, the channel estimator computes a pilot anchor ĥp using the Np pilot symbols of one time slot and a data anchor ĥs using Ns data symbols, as follows:
The channel estimator linearly interpolates between adjacent anchors ĥanchor(n−1) and ĥanchor(n) to obtain the channel estimates for the n-th slot. In accordance with a preferred embodiment of the present invention, the channel estimator separately interpolates the amplitudes and phases of the adjacent anchors.
In order to improve upon the statistical variability of the anchors, the older anchor can be averaged, as follows:
Reference is now made to
In this embodiment, the product
The methods and apparatus disclosed herein have been described without reference to specific hardware or software. Rather, the methods and apparatus have been described in a manner sufficient to enable persons of ordinary skill in the art to readily adapt commercially available hardware and software as may be needed to reduce any of the embodiments of the present invention to practice without undue experimentation and using conventional techniques.
It will be appreciated by persons skilled in the art that the present invention is not limited by what has been particularly shown and described herein above. Rather the scope of the invention is defined by the claims that follow after the appendix:
This application is a Continuation Application of U.S. patent application Ser. No. 09/438,475, filed on Nov. 12, 1999 now U.S. Pat. No. 6,603,823.
Number | Name | Date | Kind |
---|---|---|---|
5544156 | Teder et al. | Aug 1996 | A |
5867538 | Liu | Feb 1999 | A |
5887035 | Molnar | Mar 1999 | A |
6034986 | Yellin | Mar 2000 | A |
6084862 | Bjork et al. | Jul 2000 | A |
6377607 | Ling et al. | Apr 2002 | B1 |
6442218 | Nakamura et al. | Aug 2002 | B1 |
6539067 | Luschi et al. | Mar 2003 | B1 |
6603823 | Yellin et al. | Aug 2003 | B1 |
Number | Date | Country | |
---|---|---|---|
20040028154 A1 | Feb 2004 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 09438475 | Nov 1999 | US |
Child | 10632843 | US |