RU2359420C2 - Method for assessment of radio communication channel - Google Patents

Abstract

FIELD: physics, radio.

SUBSTANCE: invention may be used in reverse channel of radio communication systems of multiple access with orthogonally frequency-multiplexed signals (OFDMA), in particular, in compliance with standard 802.16. Method for assessment of reverse channel of OFDMA system consists of two stages. At the first stage correction of pilot symbols is carried out with the help of regression, and at the second stage, by means of interpolation of the first order of pilot symbols, correction of modulated data is carried out. Compared to interpolation, regression is less sensitive to accuracy of pilot signals assessment than interpolation. However, regression is more efficient for monotonous curves. Therefore, in stated method adaptive regression window is introduced, size of which is selected so that sequence of pilot signals in window is, first, monotonous, and second is sufficient for assessment of channel at specified ratio of signal/noise. Invention makes it possible to increase accuracy of communication channel assessment and therefore, to improve noise immunity of signals reception in reverse channel of radio communication systems of multiple access with orthogonal frequency multiplexed signals.

EFFECT: makes it possible to increase accuracy of communication channel assessment and therefore, to improve noise immunity of signals reception in reverse channel of radio communication systems of multiple access with orthogonal frequency multiplexed signals.

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Description

The present invention relates to the field of radio engineering, in particular to a channel estimation method in a radio communication system, and can be used in the return channel of Orthogonal Frequency Division Multiply Access (OFDMA) Orthogonal Frequency Division Multiply Access (OFDMA) signals according to 802.16 (Standard for Local and metropolitan area networks. Part 16: Air Interface for Fixed Broadband Wireless Access Systems (IEEE P802.16-REVd / D5-2004), as well as in other multiple access radio communication systems with orthogonal frequency-multiplexed signals.

In radio communication systems with orthogonal frequency-multiplexed signals, a sequence of binary symbols is received at the transmitting station. The sequence is broken into words. Each word is assigned a modulated data symbol in the form of a complex number. A sequence of modulated data symbols is converted into parallel groups of N modulated symbols. With each group perform OBPF. Convert parallel output groups of OBPF values to a serial form and supplement them with a guard interval. Thus, the frequency-multiplexed symbol represents the sum of N modulated subcarriers.

The amplitudes and phases of the subcarriers may differ from each other. However, in the time interval T _N = T _J N, where T _J is the sampling interval, the subcarriers have an integer number of periods, and the difference in the number of periods between adjacent subcarriers is one. In this case, the subcarrier spectra overlap, and the subcarriers are orthogonal to each other.

The use of multi-position types of subcarrier modulation and overlapping spectra provide a high level of spectral efficiency of radio communication systems with orthogonal frequency-multiplexed signals. (Richard van Nee, Ramjee Prasad, OFDM Wireless Multimedia Communications, Artech House, Boston-London, 2000; Prokis J. Digital Communications. Translated from English. M: Radio and Communications, 2000)

Frequency-multiplexed symbols are converted to a radio frequency and transmitted to a receiving station, where the inverse frequency conversion of the received signal is performed.

At the receiving station, the received guard interval is removed from the received orthogonal frequency-multiplexed symbols and the samples of the received symbols are converted into parallel groups. An FFT is performed with each group of N samples, thus forming N modulated symbols. After demodulation, a sequence of binary symbols is output to the receiving station.

Each frequency multiplexed symbol consists of N signal samples and

N _GP samples of the guard interval (prefix). The guard interval samples are located before the signal samples and represent the N _{GP of the} last signal samples. The duration of the guard interval is longer than the duration of the impulse response of the channel. An example of the time structure of orthogonal frequency-multiplexed symbols is shown in figure 1.

The use of the guard interval is twofold: the presence of the guard interval allows to reduce or completely eliminate intersymbol interference (i.e., acts as a guard interval in which the multipath components of one symbol are not interference from another symbol) and also allows to reduce or completely eliminate interference between subcarriers (guard interval by making the signal periodic, supports the subcarrier orthogonality). (Richard van Nee, Ramjee Prasad, OFDM Wireless Multimedia Communications, Artech House, Boston-London, 2000; Prokis J. Digital Communications. Translated from English. M: Radio and Communications, 2000)

An advantage of radio communication systems with orthogonal frequency-multiplexed signals is also their resistance to frequency selective fading. Frequency selective fading only affects a certain percentage of subcarriers. These subcarriers either do not transmit data at all, or apply methods that increase the noise immunity of data transmission (coding, adaptation of the data rate to the signal-to-noise ratio in the band affected by the fading, etc.). (Richard van Nee. Ramjee Prasad, OFDM Wireless Multimedia Communications, Artech House, Boston-London, 2000.)

Based on orthogonal frequency multiplexing, Orthogonal Frequency Division Multiply Access (OFDMA) can be implemented. With multiple access, different sets of subcarrier frequencies are used for different channels of subscriber stations (V. M. Vishnevsky, A. I. Lyakhov, S. L. Portnoy, I. V. Shakhnovich. “Broadband wireless networks for transmitting information.” Technosphere, M. , 2005).

Each user is allocated the time-frequency resource he needs. For example, in 802.16, the unit of the time-frequency resource in the return channel of multiple access radio communication systems with orthogonal frequency-multiplexed signals is a slot whose frequency band is equal to the frequency band of the subscriber station channel and the duration is equal to the duration of three orthogonally frequency-multiplexed symbols.

The time-frequency resource unit consists of minimally processed blocks. For example, in the 802.16 standard in the reverse subchannel, the minimal block to be processed is the subscriber station channel fragment shown in FIG. 2. Each fragment consists of twelve subcarriers of three orthogonally frequency-multiplexed symbols. That is, of the twelve modulated symbols, of which four symbols are pilot symbols and eight data symbols. Fragment subcarriers are adjacent in frequency. Fragments can be spaced in frequency. Interleaved OFDMA Systems are frequency-selective fading resistant.

An advantage of multiple access radio communication systems with orthogonal frequency-multiplexed signals is the ability to flexibly provide the user with a time-frequency resource for transmitting both short and long frames.

In a multiple access radio communication system with orthogonal frequency-multiplexed signals, a channel estimate is performed for coherent signal reception.

By channel estimation is meant an estimate of the complex envelope of the subcarriers of the multi-frequency signal transmitted through the propagation channel.

Channel estimation is performed using pilot symbols.

The interference immunity of OFDMA communication systems is largely dependent on the accuracy of the channel estimation.

Known channel estimation methods described by M. Morelli, U. Mengali. A Comparison of Pilot-Aided Channel Estimation Methods for OFDM Systems IEEE, Transactions on Signal Processing, vol. 49, no.12 December 2001 pp. 3065-3073. In this paper, the maximum likelihood method and the Bayesian method for estimating the impulse response of a channel using pilot symbols are considered.

In accordance with the described maximum likelihood method, an estimate of the impulse response of an OFDM symbol channel has the form

where B = {exp (-j2πi _n k / N)}, n = 0, ... N _p -1, k = 0, ... L-1, N _p is the number of pilot symbols in one OFDM symbol, i _n is the position nth pilot symbol, L is the channel length (channel impulse response length in samples), N is the FFT dimension (total number of subcarriers), Z is the vector of the values of the complex envelopes of the pilot symbols.

The channel frequency response estimate is defined as

определяется формулой (1).where G = {exp (-j2πnk / N)}, n = 0, ... N-1, k = 0, ... L-1, a

defined by formula (1).

In accordance with the Bayesian method, the estimation of the channel impulse response has the form

,

,

where С _h = E (hh ^H ) is the covariance matrix h.

определяется формулой (3).Finally, the channel frequency response estimate is determined in accordance with expression (2), where

defined by formula (3).

Known methods for channel estimation are not very effective in the return channel of multiple access radio communication systems with orthogonal frequency-multiplexed signals: firstly, the subcarriers of the subscriber station channel are spaced in frequency and therefore it is advisable to interpolate only in the time domain, and secondly, for short packets, the accuracy of statistical estimates Channel performance is very low.

Another known method is described in an article by Sinem Coleri, Mustafa Ergen, Anuj Puri and Ahmad Bahai. Channel estimation techniques based on pilot arrangement in OFDM systems. IEEE transactions on broadcasting, vol. 48, no.3, September 2002.

In this paper, the least squares method is considered.

In this method of channel estimation, N _p pilot symbols are extracted from each group of N modulated symbols (FFT output values) corresponding to a received orthogonal frequency-multiplexed signal.

For each pilot symbol, the corresponding channel estimate H _{ep is} calculated by the formula H _ep (k) = Y _p (k) / X _p (k), where Y _p (k) and X _p (k) are the input (transmitted) and output (received) values of the pilot symbol on the k-th subcarrier (1≤k≤N _p ).

From the N _p channel estimate values H _ep , the channel estimate H _{ed is} interpolated for the N _d (N = N _p + N _d ) data subcarriers.

Using the obtained channel estimate for the data subcarriers H _ed , a corresponding correction of the modulated data symbols is performed.

A device that implements the considered method is not given in the article. However, based on the description of the method, it can be assumed that the analog device consists of a read-only memory (ROM), a division unit, an interpolation unit, and a correction unit and works as follows.

The input of the analog device receives N modulated symbols (FFT output values) corresponding to the received orthogonal frequency-multiplexed symbol. Of these symbols, N _p pilot symbols are extracted, which are fed to the inputs of the division block. For each pilot symbol in the division block, the corresponding channel estimate value H _{ep is} calculated according to the formula H _ep (k) = Y _p (k) / X _p (k), where Y _p (k) and X _p (k) are respectively input (reference, transmitted) and output (received) values of the pilot symbol on the k-th subcarrier (1≤k≤N _p ). The input (reference, transmitted) values of the pilot symbols X _p (k) are supplied to the other inputs of the division unit from read-only memory (ROM).

From the outputs of the division block, the channel estimate values H _ed are fed to the interpolation block, in which according to these estimates the channel estimate is interpolated

H _ed for N _d (N = N _p + N _d ) data subcarriers. The obtained channel estimation values are sent to the inputs of the correction block. The next inputs of the correction block receive N _d data symbols. In the correction block, the corresponding correction of the modulated data symbols is performed, thus forming estimates of the modulated data symbols that are output to the block and then to the output of the device.

The described channel estimation method is not very effective in the return channel of multiple access radio communication systems with orthogonal frequency-multiplexed signals: firstly, it is advisable to interpolate in the time domain (the channel subcarriers of the subscriber station are spaced in frequency), and secondly, to implement the method, high estimation accuracy is required pilot characters.

The closest technical solution (prototype) to the claimed invention is the method described in US application US 2005/0141626 (Jun. 30, 2005).

The description of the application describes a method and system for evaluating a radio communication channel at a base station of a multiple access radio communication system with orthogonal frequency-multiplexed signals. At the same time, it is assumed that the filtering procedure for the received orthogonal frequency-multiplexed signal, amplification, transfer to the video frequency, analog-to-digital conversion, time-frequency synchronization, removal of the signal guard interval and FFT are performed.

A method for estimating a radio channel can be represented as a sequence of the following operations:

- The channel is estimated according to the preamble of the received signal and the values of the obtained estimate are stored for subcarriers corresponding only to modulated data symbols and for subcarriers corresponding to modulated data symbols and pilot symbols.

- Using the stored channel estimate values, the modulated data symbols following the preamble are corrected.

- Estimate the channel by the pilot symbols of the received signal.

- On the subcarriers with pilot symbols, the stored channel estimate values obtained from the preamble are replaced with the channel estimate values obtained from the pilot symbols.

- Using the obtained channel estimation values, the modulated data symbols are corrected.

- The phase magnitudes of the channel estimate values are calculated from the pilot symbols.

- Interpolate the obtained phase values for data symbols.

- Using the interpolated phase values, the phase of the modulated data symbols is corrected.

In the communication channel estimation method under consideration, the received signal is a sequence of frequency-multiplexed symbols. Moreover, through a given number of information frequency-multiplexed symbols, a preamble is transmitted - a known frequency-multiplexed symbol with modulated symbols on each subcarrier. Information frequency-multiplexed symbols include pilot symbols on known subcarriers.

The preamble contains known modulated symbols on all subcarriers. Therefore, the channel estimate values for all subcarriers are calculated from the preamble. Moreover, for the kth subcarrier, the channel estimate according to the preamble H _pr (k) can be calculated by the formula H _pr (k) = R _pr (k) / X _pr (k), where R _pr (k) and X _pr (k) - respectively, the received and transmitted values of the preamble symbol on the kth subcarrier. The values of the obtained channel estimate are stored.

Using the channel estimate values stored in the memory, the modulated data symbols following the preamble are corrected. Correction can be performed by the formula X _d (k) = R _pr (k) / H _pr (k), where X _d (k) are the corrected modulated symbols.

The channel is estimated by the pilot symbols of the received signal following the preamble. Channel estimation by pilot symbols can be performed in the same way as channel estimation by preamble.

On subcarriers with pilot symbols, the stored channel estimate values obtained from the preamble are replaced with channel estimate values obtained from the pilot symbols.

Using the values of the obtained channel estimate, the modulated data symbols are corrected.

The phase magnitudes of the channel estimation values ΔΘ (k) are calculated by the formula

ΔΘ (k) = arg (1 / H _pjl (k)), where H _pjl (k) is the channel estimate based on the pilot symbol for the kth subcarrier.

Interpolate the obtained phase values for the data symbols.

Using the interpolated phase values, the phase of the modulated data symbols is corrected.

The scheme for implementing the prototype device is shown in figure 3.

The device comprises series-connected first demultiplexer 1, equalizer 2, second demultiplexer 3, phase corrector 4, series-connected channel estimator according to preamble 5, multiplexer 6, memory block 7, series-connected channel estimator by pilot symbols 8 and linear interpolation block 9 . In addition, the input of the first demultiplexer 1 is the input of modulated symbols and the input of the device. The output of the first demultiplexer 1 is connected to the input of the channel estimation block according to the preamble 5. The output of the memory block 7 is connected to the second input of the equalizer 2, which is the channel estimation input according to the preamble. The second output of the second demultiplexer 3, which is the output of the pilot symbols on each subcarrier, is connected to the input of the channel estimator by pilot symbols 8, the output of which is connected to the second input of the multiplexer 6, which is the input of the channel estimate by pilot symbols. The output of the linear interpolation unit 9 is connected to the second input of the phase corrector 4, which is the input of the interpolated phase values. The output of the phase corrector 4 is the output of the estimates of the modulated data symbols and the output of the device.

The prototype device operates as follows.

From the input of the device to the first demultiplexer 1 receives a sequence of modulated symbols. Moreover, the modulated symbol sequences contain preamble symbols, information frequency-multiplexed symbols, and again preamble symbols. From the output of the first demultiplexer 1, the preamble symbols go to the input of the channel estimation block according to the preamble, and the information frequency-multiplexed symbols following the preamble go to the first input of equalizer 2.

The channel estimator in preamble 5 performs channel estimation. The preamble contains known modulated symbols on all subcarriers. Therefore, the channel estimate values for all subcarriers are calculated from the preamble. Moreover, for the kth subcarrier, the channel estimate H _pr (k) can be calculated by the formula H _pr (k) = R _pr (k) / X _pr (k), where R _pr (k) and X _pr (k) are the output, respectively (received) and input (transmitted) values of the preamble symbols on the kth subcarrier. The channel estimation values for the preamble through the multiplexer 6 are recorded in the memory unit 7.

From the memory unit 7, the channel estimate for the preamble is fed to the second input of the equalizer 2, which performs the correction of modulated symbols. The correction of modulated symbols can be performed by the formula X _d (k) = R _pr (k) / H _pr (k), where X _d (k) is the corrected modulated symbols. From the output of the equalizer 2, the modulated symbols through the second demultiplexer 3 are fed to the phase corrector 4 and the channel estimator based on the pilot symbols 8.

The channel symbol estimator 8 estimates the channel using the pilot symbols. Moreover, channel estimation by pilot symbols can be performed as well as channel estimation by preamble. From the output of the channel estimation block according to the pilot symbols 8, the channel estimation values are supplied to the multiplexer 6 and the linear interpolation block 9.

Through the multiplexer 6, the channel estimate values according to the pilot symbols are overwritten into the memory unit 7. Moreover, only the channel estimation values corresponding to the pilot symbols are overwritten. The remaining channel estimation values do not change.

In the linear interpolation unit 9, the phase values of the channel estimation values ΔΘ (k) are calculated by the formula ΔΘ (k) = arg (1 / Н _pjl (k)), where Н _pjl (k) is the channel estimate by the pilot symbol for the kth subcarrier.

Interpolate the obtained phase values for the data symbols.

The interpolated phase values are supplied to the phase corrector 4, which performs the phase correction of the modulated data symbols coming from the output of the equalizer 2 through the second demultiplexer 3 to the input of the phase corrector 4. From the output of the phase corrector 4, the modulated data symbols are sent to the output of the device.

The described method for estimating a radio communication channel is not very effective in the return channel of multiple access radio communication systems with orthogonal frequency-multiplexed signals: firstly, it is advisable to interpolate in the time domain (channel subcarriers of a subscriber station are spaced in frequency), and secondly, the method requires high accuracy of pilot estimation characters.

The problem that this invention solves is to increase the accuracy of the radio channel estimation and, thus, improve the noise immunity of receiving signals in the return channel of multiple access radio communication systems with orthogonal frequency-multiplexed signals.

To solve this problem, a method for estimating a radio communication channel is proposed, which consists in the fact that modulated symbols are stored on all channel subcarriers in a sliding window for processing signals of a given size V; on subcarriers with pilot symbols, sequences of pilot signals are allocated in a sliding window for processing signals of size V symbols, according to the sequences of pilot symbols, the size of the sliding regression window W is estimated using the obtained estimate of the size of the sliding regression window W, and the regression coefficients for the knowledge and quadrature components of the pilot symbol sequences, correct the sequence of pilot symbols located in the sliding regression window using the obtained regression coefficients, perform linear interpolation of the pilot symbols for subcarriers corresponding to the modulated data symbols, correct the modulated data symbols using the obtained interpolated pilot values characters.

Moreover, the estimation of the size of the regression window can be performed as follows: the modules of the pilot symbol sequences are computed, thus forming the sequences of the pilot symbol modules, smooth the sequences of the pilot symbol modules, the standard deviation of each smoothed sequence of the pilot symbol modules is calculated, for each smoothed sequences of pilot symbol modules verify that U of W _max smoothed pilot symbol modules are satisfied, where

W _{max the} number of pilot symbols on one subcarrier in the sliding signal processing window monotonically increases or monotonically decreases and the standard deviation of the pilot symbol modules does not exceed a given value, if the number of sequences of pilot symbol modules for which conditions are satisfied is greater than a specified number, then consider that the window size is equal to the maximum value W = W _max , otherwise the size of the sequences of the pilot symbol modules is reduced by one and again checked for compliance with the conditions that U-1 from W _max -1 of the relevant pilot symbol modules monotonically increase or decrease monotonically and the standard deviation of the values of the pilot symbol modules does not exceed a certain specified value, if these conditions are met, then W = W _max -1 if, after a given number of G checks, the conditions that the number of smoothed sequences of pilot symbol modules for which UG of W _max -G pilot symbol modules monotonically increase or monotonically decrease and for which the standard deviation of the values of the pilot symbol modules does not exceed a predetermined value, pain more than a given number are not executed, then in this case the size of the regression window is minimum W = W _min .

The values of V, W _min , W _max can be selected based on the expected signal-to-noise ratio in the channel and the maximum fading frequency.

To solve the same problem, a radio communication channel estimator is proposed, comprising a memory unit, a channel estimator according to the preamble, an equalizer, an interpolation unit, in which a parallel-serial conversion unit, a regression window estimator, a regression coefficient calculation unit, a pilot correction block are added characters, and I inputs of the device for evaluating the radio channel, where I is the number of subcarriers of the channel of the subscriber station with modulated symbols, are the inputs of the group of modulated symbols and combining they are with I inputs of the memory block and I inputs of the channel estimation block according to the preamble, the outputs of the channel estimation block according to the preamble are connected to the first group of I equalizer inputs, which are the channel estimation inputs according to the preamble, the first group of memory block outputs is connected to the second group of I equalizer inputs, which are the inputs of the stored modulated symbols, the second group of outputs of the memory block, which are the outputs of the temporary sequences of pilot symbols, is connected to the P inputs of the evaluation unit of the regression window, P inputs of the computing unit the regression coefficients, the first group of P inputs of the pilot symbol correction block, I + 1 input of the memory block and P + 1 input of the regression window estimation block are inputs of the initial installation, the output of the regression window estimation block, which is the output of the size estimation of the regression time window, is connected with P + 1 input of the regression coefficient calculation block, the second group of inputs of the pilot symbol correction block, which is the input of the calculated regression coefficients, is connected to the corresponding group of 2PK outputs of the coefficient calculation block regression, P outputs of the pilot symbol correction unit, which are outputs of the corrected pilot symbol sequences, are connected to P inputs of the interpolation unit, the outputs of which are connected to the third group I of equalizer inputs, which are inputs of interpolated pilot symbol values, I equalizer outputs are connected with I inputs of a parallel / serial conversion unit, the output of which is the output of the corrected modulated data symbols.

A comparative analysis of the proposed method for evaluating the radio channel with the prototype shows that the inventive method is significantly different from the prototype.

General features of the proposed method and prototype.

The pilot symbols are stored, the channel is estimated by the pilot symbols, and interpolation is used in channel estimation.

All other operations and their order differ from the operations of the prototype and are new.

A comparative analysis of the inventive device for evaluating a radio channel with a prototype shows that the inventive device for evaluating a radio channel is significantly different from the prototype.

Common features of the claimed device and prototype. The structure of the prototype device and the claimed device includes common blocks: a memory block, an equalizer, a channel estimation block according to the preamble, an interpolation block.

All other blocks included in the inventive device are new, the relationship between them are also distinctive features. In addition, the algorithm for estimating the radio channel is different from the prototype, therefore, the relationship between the known blocks and the newly introduced are also distinctive features.

A comparative analysis of the method for evaluating the radio channel and the device for its implementation with the prototype shows that the present invention differs significantly from the prototype, as it improves the accuracy of the evaluation of the communication channel and, thus, improves the noise immunity of receiving signals in the return channel of multiple access radio communication systems with orthogonal frequency -Multiplexed signals.

Comparison of the claimed objects of the invention with the prototype and other known technical solutions in the art did not allow to identify the totality of the claimed features and therefore they provide the claimed technical solution with the criteria of "novelty", "significant differences" and "inventive step".

Graphic materials used to illustrate the proposed solution:

Figure 1 is an example of a time structure of orthogonal frequency-multiplexed symbols.

Figure 2 is a fragment of the reverse channel OFDMA standard 802.16.

Figure 3 is a structural diagram of a prototype device.

4 is a block diagram of a multiple access radio communication system with orthogonal frequency-multiplexed signals (subscriber stations).

5 is a block diagram of a multiple access radio communication system with orthogonal frequency-multiplexed signals (base station).

6 is a structural diagram of the proposed device for evaluating the radio channel.

7 is an embodiment of a block for estimating a size of a regression window.

The proposed method for estimating a radio channel is as follows:

- On all subcarriers of the channel in a sliding window for processing signals of a given size V, modulated symbols are stored.

- On subcarriers with pilot symbols, a sequence of pilot symbols is allocated in a sliding signal processing window of size V.

- Based on the pilot symbol sequences, an estimate of the size of the W regression sliding window is performed.

- Using the obtained estimate of the size of the sliding regression window W, the regression coefficients for the in-phase and quadrature components of the pilot symbol sequences are calculated.

- Using the obtained regression coefficients, correct the sequence of pilot symbols located in the sliding regression window.

- Pilot symbols for subcarriers corresponding to modulated data symbols are linearly interpolated.

- Using the obtained interpolated values of the pilot symbols, the modulated data symbols are corrected.

Estimation of the size of the regression window can be performed, for example, in this way:

- calculate the modules of the sequences of pilot symbols, thus forming a sequence of modules of pilot symbols,

- smooth out the sequences of the pilot symbol modules,

- calculate the standard deviation of each smoothed sequence of modules of the pilot symbols,

- for each smoothed sequence of pilot symbol modules, verify that U of W _max smoothed pilot symbol modules is checked, where

W _max - the number of pilot symbols on one subcarrier in a sliding window for signal processing, monotonically increase or monotonously decrease, and the standard deviation of the pilot symbol modules does not exceed a certain specified value,

- if the number of sequences of pilot symbol modules for which conditions are greater than a given number, then it is considered that the window size is equal to the maximum value W = W _max ,

- otherwise, the size of the sequences of the pilot symbol modules is reduced by one and again checked for compliance with the conditions that U-1 of W _max -1 smoothed pilot symbol modules monotonically increase or monotonously decrease and the standard deviation of the value of the pilot symbol modules does not exceed set value

- if the conditions are met, then W = W _max -1,

- if, after a given number of G checks, the condition is that the number of smoothed sequences of pilot symbol modules for which UG from W _max -G pilot symbol modules monotonically increase or monotonically decrease and for which the standard deviation of the values of the pilot symbol modules does not exceed the specified values greater than a given number are not satisfied, then in this case the size of the regression window is minimum W = W _min .

The values of V, W _min , W _max can be selected based on the expected signal-to-noise ratio in the channel and the maximum fading frequency.

In the inventive channel estimation method, regression is applied. The regression function (line) is a line of a certain type that minimizes the error between itself and the available data (using, for example, the least squares criterion). The simplest type of regression is linear regression, in which a straight line is determined. Another type of regression is polynomial regression, in which the regression curve is determined by a polynomial. The regression line is determined by the regression coefficients. For example, for linear regression, this is the slope and offset along the abscissa of the regression line. (G. Korn and T. Korn. Handbook of mathematics. "Science", 1978; J. Bendat, A. Pirsol. Applied analysis of random data. M: "Mir", 1989; S.N. Vorobyov, L.A. Osipov. Regression analysis. St. Petersburg, 2000.)

In the description of the proposed method for evaluating a radio communication channel, it is assumed that the received orthogonal frequency-multiplexed signal is filtered, amplified, transferred to the video frequency, analog-to-digital conversion, time-frequency synchronization, removal of the signal guard interval, FFT and channel separation of subscriber stations.

The structural diagram of a multiple access radio communication system with orthogonal frequency-multiplexed signals, including radio channel estimation units, is shown in FIG. 4 (subscriber stations) and FIG. 5 (base station).

A radio communication system comprises a base station and C subscriber stations. Each of the subscriber stations contains a series-connected modulator 10, to the input of which binary symbols, a subcarrier selection device 11, an IFFT device 12, a guard interval 13 attachment device, a transmitter 14, the output of which is the output of a sequence of orthogonal frequency-multiplexed symbols, are input.

From subscriber stations through the communication channels 15 sequences of orthogonal frequency-multiplexed symbols arrive at the base station. The base station contains a serially connected antenna 16, a receiver 17, a guard interval removal device 18, an FFT device 19, a channel allocator 20 of the subscriber station, the outputs of which are connected respectively to the inputs J of the radio channel estimators 21-1-21-J. The output of each of the J devices for evaluating the radio channel 21-1-21-J is connected to the input of one corresponding to it from J demodulators 22-1-22-J, the outputs of which are the outputs of the system. The second output of the receiver 17 is connected to the inputs of the initial installation of the device to remove the guard interval 18, the FFT device 19, the channel allocation device of the subscriber station 20 and the radio channel estimation device 21-1-21-J.

The radio communication system operates as follows. A subscriber station receives a sequence of binary characters. In modulator 10, the sequence is divided into words consisting of d characters (d = 1,2 ... D). Each word is assigned a modulated data symbol in the form of a complex number.

In the subcarrier selection device 11, the sequence of modulated data symbols is converted into parallel groups of two types, the first of which consists of Q ₁ modulated data symbols, where Q ₁ is a given positive integer, and the second is of Q ₂ modulated data symbols, where Q ₂ is given positive integer. Groups of the first type Z are supplemented with zero characters (zeros), with Q ₁ + Z = N, where Z and N are given positive integers, and the location of the modulated and zero characters in the group is specified. Groups of the second type Z are supplemented with zero symbols (zeros), and every N _f modulated data symbols have a pilot symbol, where N _f = Q ₂ / K, with Q _{2 being a} multiple of K and Q ₂ + Z + K = N, and K - the number of pilot symbols in the group of the second type.

The location of the modulated and null characters in the group is specified. A sequence of groups of the first and second types is formed in such a way that groups of the second type follow every N _t groups of the first type, where N _t is a given positive integer.

In the IFFT device 12, an inverse fast Fourier transform is performed with each group of the generated sequence.

In the attachment device of the guard interval 13, parallel output groups of inverse fast Fourier transform values are converted into a serial form, thereby forming a sequence of transmitted symbols, each of which contains N received consecutive inverse fast Fourier transform values, and complement each transmitted symbol with a guard interval, forming thus a sequence of orthogonal frequency multiplexed symbols.

The transmitter 14 through the communication channel 15 transmits a sequence of orthogonal frequency-multiplexed symbols to the base station.

The base station antenna receives signals from subscriber stations. After time and frequency synchronization, these signals become orthogonal (coincide in time and spaced in frequency).

At the base station, the sequences of orthogonal frequency-multiplexed symbols received by the receiver 17 are sent to the guard interval deletion device 18, where the guard interval is deleted, thereby forming a sequence of received symbols and converting the received symbols into parallel groups of input values.

In the FFT device 19, a fast Fourier transform is performed with each group of input values, thus forming N modulated symbols in each group.

In the device for selecting channels of subscriber stations, 20 of the N modulated symbols extract C sets of modulated symbols corresponding to C channels of subscriber stations, where C is the number of subscriber stations in the communication system, and takes values from 1 to J, where J is the maximum number of subscriber stations in the communication system . From the outputs of the device for allocating channels of subscriber stations 20 From sets of modulated symbols, they arrive at C of the corresponding device for evaluating the radio channel 21. The rest (J-C) devices for evaluating the channels of radio 21 from the device for allocating channels of the subscriber stations 20 receive zeros.

In each radio channel estimator 21-1-21-J, the channel estimation of the subscriber station is performed using the pilot symbols. Using the obtained channel estimation results of subscriber stations, the modulated data symbol is evaluated, forming groups of modulated data symbol estimates. Then, the groups of estimates of the modulated data symbols are converted into a serial form, thereby forming a sequence of estimates of the modulated data symbols.

In the demodulator 22-1-22-J, demodulation of the obtained estimates of the modulated data symbols is performed, thus forming a sequence of binary data.

The initial setup signal, as a rule, is supplied to all devices of receiving and transmitting stations. This signal is not essential for understanding the operation of the device and therefore it is indicated only on electrical circuits. However, for a better understanding of the operation of the device in figure 5, such a signal is indicated.

The structural diagram of the inventive device for evaluating the radio channel 21 for implementing the inventive method is presented in Fig.6.

The radio channel estimator 21 comprises a memory unit 23, a channel estimator according to preamble 24, an equalizer 25, a parallel / sequential conversion unit 26, a regression window estimator 27, a regression coefficient calculation unit 28, a pilot symbol correction unit 29, a linear interpolation unit 30 .

The I inputs of the radio channel estimator 21 are the inputs of the group of modulated channel symbols of the subscriber station and are combined with the I inputs of the memory block 23 and the I inputs of the channel estimator according to the preamble 24. The outputs of the channel estimator according to the preamble 24 are connected to the first group I of equalizer inputs 25, which are the channel estimation inputs for the preamble. The first group of outputs of the memory block 23 is connected to the second group I of inputs of the equalizer 25, which are inputs of stored modulated symbols. The second group of outputs of the memory block 23, which are the outputs of the temporary sequences of pilot symbols, is connected to the P inputs of the evaluation unit of the regression window 27, P inputs of the unit for calculating the regression coefficients 28, the first group of P inputs of the block of correction of the pilot symbols 29. I + 1 block input memory 23 and P + 1 the input of the evaluation unit of the regression window 27 are the inputs of the initial installation. The output of the regression window estimation block 27, which is the output of the regression time window size estimation, is connected to the P + 1 input of the regression coefficient calculation block 28. The second group of inputs of the pilot symbol correction block 29, which are the inputs of the calculated regression coefficients, is connected to the corresponding 2PK group the outputs of the block for calculating the regression coefficients 28. The P outputs of the block for correcting pilot symbols 29, which are the outputs of the corrected sequences of pilot symbols, are connected to the P inputs of the block interpol 30, the outputs of which are connected to the third group I of the inputs of the equalizer 25, which are inputs of interpolated values of the pilot symbols. The I outputs of the equalizer 25 are connected to the I inputs of the parallel / serial conversion unit 26, the output of which is the output of the estimates of the modulated data symbols.

A device that implements the inventive method works as follows.

At the I inputs of the radio channel estimator 21, where I is the number of subcarriers of the channel of the subscriber station, groups of modulated channel symbols of the subscriber station are received, each of which consists of I parallel modulated symbols. Moreover, each of the I modulated symbols corresponds to one of the I subcarriers of the channel of the subscriber station.

Groups of I modulated symbols from the inputs of the device are fed to the inputs of the channel estimation block according to preamble 24 and memory block 23.

In the channel estimator for the preamble 24, the channel is evaluated for the preamble of the received signal. The channel estimate values for the preamble are sent to the I inputs of the equalizer 25. Using the channel estimate values, the modulated data symbols following the preamble are corrected in the equalizer 25.

The groups of modulated symbols following the preamble are recorded in a memory block 23, which consists of I series-parallel registers, each with a length of V cells. One of I modulated symbols is written in each register. After the arrival of a new group of I modulated symbols, the modulated symbols recorded in the registers in each register are shifted by one cell. After the arrival of V groups of I modulated symbols, I * V modulated symbols are recorded in the memory block. After the group of modulated symbols arrives at the input of the memory block V + 1, which, after shifting the modulated symbols, are recorded in the first register cells, the modulated symbols of the second group are written in the last register cells instead of the I modulated symbols of the first group. Thus, on all I channel subcarriers in the moving time window for processing signals of a given size V, I * V modulated symbols are stored.

In the memory unit 23, pilot symbols are read in parallel from the registers corresponding to the subcarriers with pilot symbols. Thus, on each of the P subcarriers with pilot symbols, in the moving time signal processing window of size V, time sequences of pilot symbols are extracted, thus obtaining P time sequences of pilot symbols, each of which includes time-following one after another pilot symbols of the same subcarrier. Temporary sequences of pilot symbols from the P outputs of the memory block are fed to the inputs of the block for estimating the size of the regression window 27, the block for calculating the regression coefficients 28, and the block for correcting the pilot symbols 29.

In the block for estimating the size of the regression window 29, the sequence of pilot symbols is used to estimate the size of the regression window W. From the output of the block for estimating the size of the regression window, the size of the regression window is fed to the input of the regression coefficient calculation unit 28.

In the block for calculating the regression coefficients 28, using the obtained estimate of the size of the moving time regression window W, the regression coefficients for the pilot symbol sequences received from the memory block P are calculated. The number of regression coefficients K for one in-phase or quadrature sequence of pilot symbols is determined by a given regression order.

The calculation of the regression coefficients is described in the books: G. Korn and T. Korn. Math reference. Science, 1978; J. Bendat, A. Pirsol. Applied random data analysis. M .: "World", 1989; S.N. Vorobiev, L.A. Osipov. Regression analysis. St. Petersburg, 2000. The easiest way to calculate the regression coefficients is on a microprocessor, ie implement a unit for calculating regression coefficients based on a microprocessor.

With 2PK outputs of the regression coefficient calculation unit 28, the calculated regression coefficients are fed to the inputs of the pilot symbol correction unit 29.

In the block of pilot symbol correction 29, using the obtained regression coefficients for the in-phase and quadrature components of the pilot symbol sequences, the pilot sequences received from the memory block P are corrected. The correction of the complex values of the pilot symbols can be performed by replacing their values with the values of the correlation line at the points corresponding to the values of the pilot symbols. The corrected P sequences of pilot symbols are supplied to interpolation unit 30.

In the linear interpolation unit 30, the corrected pilot symbol values are stored and the pilot symbol values for the subcarriers corresponding to the modulated data symbols are interpolated from them.

Interpolation is described in books: N.S. Bakhvalov. Numerical methods. "Science", 1973; G. Korn and T. Korn. Math reference. Science, 1978; J. Bendat, A. Pirsol. Applied random data analysis. M .: Mir, 1989. The easiest way to interpolate is to perform on a microprocessor, i.e. implement microprocessor-based interpolation block.

From the I outputs of the interpolation unit 30, the interpolated values of the pilot symbols are fed to the I inputs of the equalizer 25.

The other I inputs of the equalizer 25 from the memory unit 23 in parallel receive the values of modulated data symbols.

In the equalizer 25, using the interpolated pilot symbol values obtained in the interpolation unit 30, the modulated data symbols are corrected. Pilot symbols have a unit amplitude and a zero phase. Therefore, the correction of the data symbols is carried out by dividing them by the interpolated values of the pilot symbols. Equalizer 25 can be implemented based on the division schemes of complex numbers.

From the output of the equalizer 25, the data symbols are sent to the parallel / serial conversion unit 26. In the parallel / serial conversion unit 26 I, the parallel modulated symbols are converted to serial form. Block parallel / serial conversion 26 can be performed on the basis of parallel / sequential registers, and the modulated characters are written to the register in parallel, and read sequentially.

The estimation of the size of the regression window, the calculation of the regression coefficients, the correction of pilot symbols, the interpolation of pilot symbols and the correction of modulated data symbols in the equalizer 25 are performed each time the memory block 23 is received at the input and the L groups of parallel I input modulated groups are shifted in its parallel-parallel registers characters, where L is the number of orthogonally frequency-multiplexed characters overlapping in time by one fragment of the channel of the subscriber station. For example, for the standard 802.16 L = 3 (figure 2). At the same time, in the equalizer 25, the modulated data symbols belonging to the fragments of the subscriber station channel located in the center of the regression window are corrected. Those. in the memory block 23, from each of the I registers to the equalizer 25, modulated data symbols of the channel fragment of the subscriber station located in the center of the regression window are read (at the same distance from one and the other end of the regression window).

An embodiment of the block for estimating the size of the regression window 27 is shown in FIG. The block for estimating the size of the regression window 27 contains a node for calculating the modules 31, a node for smoothing 32, a node for calculating the standard deviation 33, a node for checking the monotonicity 34, a node for checking the conditions for completing calculations 35, a node for comparing the threshold 36, counter 37, ROM 38, the first subtraction node 39 , second subtraction node 40, register 41.

The unit for estimating the size of the regression window 27 is as follows.

At the P inputs of the regression window size estimator, P sequences of pilot symbols are received. These sequences arrive at the node for calculating the pilot symbol modules 31, which can be implemented as P parallel schemes for calculating the module of a complex number. In the node for calculating the pilot symbol modules 31, the pilot symbol modules P of the pilot symbol sequences are computed, thereby forming a sequence of pilot symbol modules.

At smoothing unit 32, sequences of pilot symbol modules are smoothed. Smoothing the sequence of pilot symbol modules can be performed by various methods, for example, by digital filtering, cubic interpolation, etc. However, from the point of view of practical implementation and the amount of computational cost (for example, on a microprocessor), cubic interpolation is most preferable. Cubic interpolation is described in the book of L.I. Turchak. Fundamentals of numerical methods. Moscow, Nauka, 1987, chapter 2. Smoothed sequences of pilot symbol modules are sent to the standard deviation calculation unit 33 and the monotonicity verification unit 34.

At the root mean square deviation calculation unit 33, the standard deviation of the pilot symbol modules of each smoothed sequence of pilot symbol modules is calculated.

At the monotonicity checking unit 34, for each smoothed sequence of pilot symbol modules, the condition that the U of W _max smoothed pilot symbol modules monotonically increase or monotonically decrease is checked. The values of U and W _max are supplied to the monotonicity checking unit 34 from the first 39 and the second subtraction unit 40, respectively. The monotonicity checking unit 34 can be implemented based on sequentially checking the inequality relationship (more or less) of two adjacent pilot symbol modules and counters to calculate the comparison results.

In the node for checking the conditions for completing calculations 35, the number of sequences is determined for which two conditions are satisfied: the sequence is monotonic and the standard deviation of the pilot symbol modules does not exceed a predetermined value. The node for checking the end conditions of calculations 35 can be implemented on the basis of a counter of the number of monotone sequences, a comparison scheme of the standard deviation of the module of each sequence of pilot symbol modules with a threshold, and a counter of the number of standard deviations that exceed the threshold. The output node verification conditions for the completion of calculations 35 receives the number of sequences satisfying these two conditions. These sequences are then sent to the comparison node with threshold 36. If the threshold is exceeded, then from the second output of the comparison node with threshold 36, the signal goes to the input of register 41. If the threshold is not exceeded, then from the first output of the comparison node with threshold 36, the signal goes to the counter input 37.

From the first output of the ROM 38, the value U is supplied to the first input of the first subtraction unit 39, and the value W _{max is} supplied to the first input of the second subtraction unit 40. The second inputs of the first 39 and second 40 nodes subtraction receives the value of the counter 37. In the initial state, the counter 37 recorded zero. Therefore, the value U is received from the output of the first subtraction node 39 to the monotonicity verification node 34, and the value of W _{max is} received from the output of the second subtraction node 40 to the monotonicity verification node 34 and the register 41.

If a threshold exceeding signal is received from the comparison node with threshold 36 to the register 41, then the signal W _{max is} written to the register 41 from the second subtraction node 40 and the maximum regression window size W = W _max is sent to the output of the block. Otherwise, if the signal indicating that the threshold is not exceeded is received from the comparison node with threshold 36 to the counter 37, then the value of counter 37 is increased by one, and the number U-1 is sent to the input of the monotonicity verification node 34 from the first subtraction node 39 from the second node subtraction 40 to the input of the node monotonicity verification 34 and the register 41 receives the number W _max -1.

The size of the following P sequences of pilot symbol modules in the monotonicity checking unit 34 is reduced by one. In the node for checking the conditions for completing calculations 35, the number of shortened sequences is determined for which two conditions are satisfied: the sequence is monotonic and the standard deviation of the pilot symbol modules does not exceed a predetermined value. The output node verification conditions for the completion of calculations 35 receives the number of sequences satisfying these two conditions. These sequences then go to the comparison node with threshold 36. If the threshold is exceeded, then from the second output of the comparison node with threshold 36, the signal goes to the input of register 41 and the size of the regression window W = W _max -1 is sent to the output of the regression window estimation block 27. If the threshold is not exceeded, then from the first output of the comparison node with threshold 36, the signal is supplied to the input of counter 37.

If, after a given number of G checks, the conditions that the number of smoothed sequences of pilot symbol modules for which UG from W _max -G pilot symbol modules monotonically increase or monotonically decrease and for which the standard deviation of the values of the pilot symbol modules does not exceed a predetermined value , more than a given number, are not executed, then in this case the size of the regression window is minimum W = W _min .

Thus, the inventive method of estimating the return channel of the OFDMA system consists of two stages. At the first stage, using the regression, the correction of pilot symbols is performed, and at the second, by interpolation of the first order of pilot symbols, the correction of modulated data is performed.

Unlike interpolation, regression does not require the curve to pass through predetermined points. Therefore, regression is less sensitive to pilot error estimation than interpolation. However, regression is most effective for monotonic curves. Therefore, in the inventive method, an adaptive regression window is introduced, the size of which is selected so that in the window the sequence of pilot symbols is, firstly, monotonic, and secondly, sufficient to estimate the channel at a given signal to noise ratio.

The advantage of the proposed method for first-order regression is also the simplicity of its implementation.

Claims (3)

1. A method for evaluating a radio communication channel, which consists in the fact that modulated symbols are stored on all channel subcarriers in a sliding window for processing signals of a given size V; on subcarriers with pilot symbols, in a sliding window for processing signals of size V, sequences of pilot symbols are extracted from pilot of characters perform an estimate of the size of the sliding regression window W, using the obtained estimate of the size of the sliding regression window W, the regression coefficients for the in-phase and quadrature components n sequences of pilot symbols, the pilot symbol sequence is corrected in sliding window regression using the obtained regression coefficients, performs linear interpolation of pilot symbols for respective subcarriers modulated data symbols is corrected modulated data symbols using the interpolated values received pilot symbols. 2. The method according to claim 1, characterized in that for estimating the size of the regression window, the pilot symbol sequence modules are computed, thus forming pilot symbol module sequences, the pilot symbol module sequences are smoothed, the standard deviation of each smoothed sequence of pilot symbol modules is calculated, for each smoothed sequences of pilot symbol modules verify that U of W _max smoothed pilot symbol modules, where W _{max is the} number of pilot symbols per tray in the moving signal processing window monotonously increase or monotonically decrease and the standard deviation of the pilot symbol modules does not exceed a given value, if the number of sequences of pilot symbol modules for which conditions are greater than a specified number, then it is considered that the window size is equal to the maximum value W = W _max otherwise, the amount of pilot symbol sequences modules is decremented by one and again checked for compliance with the conditions that the U - 1 of W _max - 1 modules smoothed monotone pilot symbols to increase or decrease monotonically and standard deviation value of the modules of pilot symbols does not exceed a predetermined value, if these conditions are satisfied, then W = W _max - 1 if after the predetermined number G checks the conditions that the number of the smoothed sequence of modules pilot symbols for where U - G of W _max - G pilot symbols modules increase monotonically or decrease monotonically and for which the standard deviation values modules pilot symbols does not exceed a predetermined value greater than the predetermined number is not met, t In this case, the regression minimum window size W = W _min. 3. The method according to claim 2, characterized in that the values of V, W _min and W _max are selected based on the expected signal-to-noise ratio in the channel and the maximum fading frequency.

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