KR100326158B1 - Channel estimating compensation apparatus of receiver in cdma mobile communication equipment - Google Patents

Abstract

The present invention relates to a channel compensation device in a receiver of a code division multiple processing mobile communication system, and more particularly, to a channel compensation device using weights and linear interpolation of pilot symbols. The present invention provides a code division multiple processing mobile communication system receiver, comprising: an observation section indicator indicating an observation section including a channel compensation estimation block to be compensated when receiving data, and extracting a pilot symbol from the received data of the observation section; A pilot symbol extraction timing section for outputting a pilot symbol extraction timing signal for storing the received data of the specified observation section and outputting a pilot symbol in the observation section by the pilot symbol extraction timing signal; And a channel estimator for obtaining two first and second preprocessing estimates, a slope between the first and second preprocessing estimates, and outputting a channel estimate according to the slope, and the channel compensation estimation block. A delayed delay output and a channel compensation estimation block And it receives the channel estimate, characterized by made of an estimated channel compensator for compensating for channel degradation of the channel estimation compensation block based on the channel estimate.

Description

CHANNEL ESTIMATING COMPENSATION APPARATUS OF RECEIVER IN CDMA MOBILE COMMUNICATION EQUIPMENT}

The present invention relates to a channel compensation device in a receiver of a code division multiple processing mobile communication system, and more particularly, to a channel compensation device using weights and linear interpolation of pilot symbols.

In general, in a mobile communication system, deterioration of received data occurs during data transmission. The deterioration of the received data may occur due to the multipath occurring in the transport channel. In order to compensate for the deterioration occurring on the transmission channel, a signal known to the base station and the terminal, that is, a pilot signal, is inserted into the data during transmission. When the data in which the pilot signal is inserted is transmitted on the transmission channel, the receiver receives the data and detects the pilot signal included in the data to compensate for the degradation of the data. In general, two methods are used. The first method uses weights of pilot signals, and the second method uses linear interpolation methods using slopes of two pilot signals.

First, a configuration of a receiver of a general code division multiple processing mobile communication system will be described with reference to FIG. 1, and a method for compensating for channel degradation will be described with reference to FIGS.

Reference numeral 110 in FIG. 1 is a finger. A plurality of fingers 110 are present in the receiver, and each finger 110 has a different channel. Typically, the finger 110 is composed of a despreader 101, a pilot symbol extractor 103, a channel estimator 105, and a channel compensator 107 to compensate for channel degradation. The despreader 101 receives the received data spread by the PN code or the like during transmission, and despreads and outputs the converted data to convert the data before spreading. The pilot symbol extractor 103 receives the received data output from the despreader 101 and extracts a pilot symbol included in the received data. The pilot symbol extracted by the pilot symbol extractor 103 is input to the channel estimator 105, and the received data from which the pilot symbol is extracted is input to the channel compensator 107. The channel estimator 105 receives the pilot symbol and checks a channel state and outputs a channel compensation signal. The channel compensator 107 receives the received data, receives a channel compensation signal from the channel estimator 105, and compensates for and degrades the received data. The received data output from the channel compensator 107 is added to the other received data output from the other finger 110 by the adder 111 to restore the original data through the synchronous detector 113, the determiner 115, and the channel decoder 117.

In general, the channel estimator 105 estimates the average of the pilot symbols, which are transmission reference data, and estimates the average of the pilot symbols. In this method, the estimated value does not reach the actual value.

Due to these drawbacks, the first method, which is a method of multiplying an estimate by a pilot symbol with an appropriate weight, is used to vary the effect on the estimation of the pilot symbol used for the estimation of each observation interval.

FIG. 2A is a diagram illustrating a data block in a time domain according to a channel estimation method using a general weight, and FIG. 2B is a conceptual diagram of a channel estimator for channel estimation using a weight.

Hereinafter, referring to FIG. 2, a first channel degradation compensation method will be described. As shown in FIG. 2A, a transport channel has a plurality of slots in a time domain, and each slot is 0.625 ms. Each slot has a different amplitude due to an error caused by multiple paths on the transmission channel. In FIG. 2, the hatched portions represent slots to be estimated (hereinafter, referred to as 'estimated data blocks').

FIG. 2B is a conceptual diagram of the channel estimator 105 according to the first method and includes a plurality of multipliers 108 and a summer 106. First, a plurality of observation sections are designated for a time slot section based on the estimated data block, and the pilot symbols corresponding to the respective observation sections are compared with the reference pilot symbols, and the amplitudes of the pilot symbols in the observation section are determined. In view of the degradation environment of the reception channel, the weighted value a (n) of the channel variation is obtained from the channel estimate of the pilot symbol corresponding to each time slot, and the weights a A method of compensating for channel error by multiplying a weight obtained by (n) and summing values output from the respective multipliers 108 by adding them in a summer 106 is performed.

By using the first method, it is possible to maintain better performance than the method of compensating for channel error by averaging only pilot symbols, but has a disadvantage in that it does not have good performance in a channel environment having fast fading.

In the second method, as shown in FIG. 3, when a channel is estimated using a pilot symbol, a channel is compensated using an estimated value linearly interpolated using two estimated symbols in an area that cannot be estimated with time. Specifically, the channel estimation compensation block obtains an estimate based on the n, n + 1th pilot symbols in consideration of deterioration according to the channel environment using an existing pilot required for channel estimation, and obtains a slope of the obtained estimate to compensate for the interval. A method of estimating and compensating a channel by interpolating a channel estimation compensation value to a value corresponding to the slope fs.

However, the second method has a disadvantage in that performance is slower than the first method in a slow fading environment. This is because amplification of received data increases in a slow fading environment.

Accordingly, an object of the present invention is to provide a channel estimation compensation device of a receiver of a code division multiple processing mobile communication system capable of simultaneously applying weights and linear interpolation to prevent degradation of a received signal due to a change in channel environment.

In order to achieve the above object, the present invention provides a code division multiple processing mobile communication system receiver comprising: an observation section indicator indicating an observation section including a channel compensation estimation block to be compensated when receiving data, and received data of the observation section; A pilot symbol extraction timing unit for outputting a pilot symbol extraction timing signal for extracting a pilot symbol from the storage unit; storing received data of the specified observation section, and outputting a pilot symbol in the observation section by the pilot symbol extraction timing signal; A channel estimator for obtaining two first and second preprocessing estimates using a memory, the pilot symbols, and the weighting coefficients, obtaining a slope between the first and second preprocessing estimates, and outputting a channel estimate according to the slopes; A delay unit for outputting a delayed compensation estimation block by a predetermined time; And a channel estimation compensator configured to receive the channel compensation estimation block and the channel estimate and compensate for channel degradation of the channel compensation estimation block according to the channel estimate.

1 is a block diagram of a receiver of a typical code division multiple processing system.

2A illustrates a data block according to a channel estimation method using a general weight.

2B is a conceptual diagram of a channel estimator for channel estimation using weights.

3 is a diagram illustrating a data block according to a channel estimation method using general linear interpolation.

4A illustrates a data block according to a channel estimation method using weights and linear interpolation, according to an embodiment of the present invention.

4B is a conceptual diagram of a channel estimator according to an embodiment of the present invention.

5 is a detailed block diagram of a channel estimator in accordance with an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals have the same reference numerals as much as possible even if displayed on different drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

4A is a diagram illustrating a data block according to a channel estimation method using weights and linear interpolation according to an embodiment of the present invention, and FIG. 4B is a conceptual diagram of a channel estimator according to an embodiment of the present invention.

Referring to FIG. 4, in FIG. 4A, the number of slots to be observed is determined, and the slots to be observed are divided into two slot groups. That is, the one slot group is composed of three slots as shown in FIG. When the number of slots to be observed, that is, the observation interval and the slot group, is determined, first, an estimate of the pilot symbol for each slot of each slot group is obtained. Then, the slope f _s between each obtained two pilot symbol estimates is obtained and the channel error is compensated using the obtained slope fs. The number of slots in the observation section observed in FIG. 4A is six. In the above example, FIG. 4B divides the observed slots into two, and divides the slots into two slot groups, each of which is divided into three slots. The weighted weights are multiplied by the multiplier 121 to obtain each pilot symbol estimate. The pilot symbol estimates of each of the two slot groups are summed in summer 125 to output two preprocessing estimates. The linear interpolator 129 receives the two preprocessing estimates, obtains a slope f _s between the preprocessing estimates, and outputs a final estimate according to the slopes.

FIG. 5 is a detailed block diagram of a channel estimator according to an exemplary embodiment of the present invention. Referring to this, a channel error compensation method according to the present invention will be described in detail.

The observation section indicator 131 outputs an observation section indication value (ov_num) to designate a section to be observed when receiving data. As a method for setting the section to be observed, it may be variably indicated by a bit error rate (BER) of the received data and may be fixedly indicated. The pilot symbol extraction timing unit 135 outputs a timing signal for extracting a pilot symbol from the received data. The memory 133 receives the received data output from the despreader 101 of FIG. 1, receives the observation section indication value from the observation section indicator 131, stores received data of the predetermined slot section to be observed, and the pilot symbol extraction timing unit 135. A timing signal is input from the pilot signal to extract pilot symbols from the received data of each slot. The transmission pilot pattern generator 137 generates and outputs a pilot pattern that is known to the base station and the terminal. The comparator 139 compares the pilot symbols output from the memory 133 and the transmission pilot patterns output from the transmission pilot pattern generator 137 to detect difference values according to channel degradation, respectively, and divides the observation interval by two, and thus the first channel estimator 145. Output to the second channel estimator 147, respectively. The weighting coefficient generator 141 provides the weighting coefficient normalized according to the position of each slot from the estimated data block to the first channel estimator 145 and the second channel estimator 147, respectively. The first channel estimator 145 outputs a difference value between each of the plurality of pilot symbols and the transmission pilot pattern for one of two observation intervals output from the comparator 139 and for each pilot symbol in the first coefficient generator 141. The pilot symbol estimates are respectively output by multiplying the weighting factors, and the pilot symbol estimates are summed to output a preprocessing estimate (hereinafter, referred to as a first preprocessing estimate). The second channel estimator 147 outputs a difference value between each of the plurality of pilot symbols and the transmission pilot pattern for one of two observation intervals output from the comparator 139, and the weights output for each pilot symbol from the coefficient generator 141. The pilot symbol estimates are respectively output by multiplying the coefficients, and the pilot symbol estimates are summed to output a preprocessing estimate (hereinafter referred to as a second preprocessing estimate). The linear interpolator 129 receives the first and second preprocessing estimates, obtains a slope of the first and second preprocessing estimates, and outputs a final channel estimate. The inclination is obtained by Equation 1 below.

(Equation 1)

The delay unit 149 receives a channel estimation compensation block among the received data output from the despreader 101, delays the time for obtaining the final channel estimate, and then outputs the delay. The channel estimation compensator 151 receives a channel estimation compensation block from the delayer 149, receives a channel estimate from the linear interpolator 129, and compensates and deteriorates data degradation of the channel estimation compensation block.

As described above, the present invention has an advantage of having good reception performance in a slow fading environment and a fast fading environment by compensating for channel degradation using a weight and linear interpolation method.

Claims (12)

Claim 1 has been deleted. Claim 2 has been deleted. Claim 3 has been deleted. Claim 4 has been deleted. Claim 5 has been deleted. Claim 6 has been deleted. Claim 7 has been deleted. In the code division multiple processing mobile communication system receiver, An observation section indicator indicating an observation section including a channel compensation estimation block to be compensated when the received data is input; A pilot symbol extraction timing unit for outputting a pilot symbol extraction timing signal for extracting pilot symbols from the received data of the observation section; A memory for storing received data of the designated observation section and outputting a pilot symbol in the observation section by the pilot symbol extraction timing signal; A channel estimator for calculating two first and second preprocessing estimates using the pilot symbols and weighting coefficients, obtaining a slope between the first and second preprocessing estimates, and outputting a channel estimate by the slopes; A delay unit for delaying and outputting the channel compensation estimation block for a predetermined time; And a channel estimation compensator receiving the channel compensation estimation block and the channel estimate and compensating for the channel degradation of the channel compensation estimation block according to the channel estimate. The method of claim 8, wherein the channel estimator, A transmission pilot pattern generator for outputting a transmission pilot pattern known to the base station and the terminal; The pilot symbols of the observation section are divided into two first and second observation intervals, each of the pilot symbols is compared with the transmission pilot pattern to obtain a difference value, and the divided first observation interval and the second observation interval are used. A comparator that outputs a corresponding difference value, A weighting factor generator for outputting a weighting factor normalized according to a pilot symbol position from the channel compensation estimation block; A first channel estimator for receiving the difference value of each of the first observation intervals and a corresponding weighting coefficient and outputting the first preprocessing estimate; A second channel estimator for receiving a difference value of each of the second observation intervals and a corresponding weighting coefficient and outputting the second preprocessing estimate; And a linear interpolator for calculating slopes of the first and second preprocessing estimates and outputting channel estimates according to the slopes. The method of claim 9, wherein the first channel estimator, A plurality of multipliers outputting respective pilot symbol estimates by multiplying a plurality of difference values for the first observation interval and a weighting factor corresponding to each of the pilot symbols in the observation interval; And a plurality of adders for adding pilot symbol estimates output from a multiplier and outputting a first preprocessing estimate. The method of claim 9, wherein the second channel estimator, A plurality of multipliers outputting respective pilot symbol estimates by multiplying a plurality of difference values for the second observation interval and a weighting factor corresponding to each of the pilot symbols in the observation interval; And a combiner for summing pilot symbol estimates output from the plurality of multipliers and outputting a second preprocessing estimate. The method of claim 9, And the slope is calculated by the following equation. (Equation 1)