KR100304670B1 - Apparatus and method for estimating channel using pilot and traffic channel and DS/CDMA receiver comprising it - Google Patents

Abstract

The present invention relates to a channel estimator using a pilot and a traffic channel, a method thereof, and a direct sequence code division multiple access receiver having the same. The channel estimator using the pilot and traffic channels despreads a received pilot channel and despreads the received pilot channel. A first channel estimator for estimating a channel from the pilot signal; Despread the received traffic channel, demodulate user data included in the traffic channel by the channel estimated by the first channel estimator from the despread traffic signal, remove demodulated data from the despread signal, and demodulate A second channel estimator estimating a channel from the signal from which data is removed; And a combiner for coupling the output of the first channel estimator and the output of the second channel estimator.

According to the present invention, a channel estimation without time delay is performed by using a pilot channel and a traffic channel together to obtain a relatively smaller E _b / N ₀ ratio than when a channel is estimated using only a pilot channel.

Description

Channel estimator using pilot and traffic channels, method and direct sequence code division multiple access receiver having same {Apparatus and method for estimating channel using pilot and traffic channel and DS / CDMA receiver comprising it}

The present invention relates to a channel estimator using a pilot channel and a traffic channel, a method thereof, and a direct sequence code division multiple access (DS / CDMA) receiver having the same. A channel estimator for estimating a channel from a traffic channel as well as a time pilot channel, a method thereof, and a DS / CDMA receiver having the same.

Currently used DS / CDMA systems have a pilot channel in the forward connection so that each mobile station in the cell coherently detects the signal received from the base station while detecting and responding to the characteristics of the radio channel.

The pilot channel causes the mobile station to obtain timing for the CDMA forward channel. That is, the pilot channel provides a phase reference for coherent demodulation and also provides the mobile station with the means to compare the strength of the signals coming from nearby base stations to determine handoff. There is one pilot channel per cell, and the power of the pilot channel is transmitted larger than that of the traffic channel through which the user signal is multiplexed and transmitted. Accordingly, in the forward connection, channel estimation is performed using only the pilot channel, and coherent demodulation is performed using the pilot channel. In the reverse link, non-coherent demodulation eliminates the need for channel estimation.

However, since non-coherent demodulation is inferior in performance to coherent demodulation, coherent demodulation is proposed in a next generation system using a pilot signal even in a reverse connection.

Channel estimation is used not only for coherent demodulation but also for diversity (space diversity) techniques to overcome distortion of the signal due to multipath fading. Diversity may be classified into selection combining, equal gain combining, and maximum ratio combining according to a method of using a plurality of received signals in a receiver. Double maximum noncoupling is a method of maximizing the signal-to-noise ratio (SNR) in an environment where each signal is received with additive white gaussian noise by combining each signal by the ratio of the magnitude of the signal.

As such, in order to use a diversity scheme for overcoming multipath fading, channel size and phase information of a received signal are required. Therefore, accurately estimating the size and phase of a channel in a fading channel environment is an important factor in determining the performance of the diversity scheme.

Channel estimation is usually performed using only pilot channels. However, since the traffic channel also passes through the same channel as the pilot channel, not only the pilot channel but also the traffic channel has channel information. Therefore, it is preferable to perform channel estimation using the traffic channel.

An object of the present invention is to provide a channel estimator for estimating a channel using not only a pilot channel but also a traffic channel, a method thereof, and a DS / CDMA receiver having the same.

1 is a block diagram of a channel estimator using a pilot channel and a traffic channel according to the present invention.

FIG. 2 is a block diagram of a DS / CDMA receiver with a channel estimator shown in FIG.

FIG. 3 shows the energy-to-noise ratio (E _b / N ₀ ) required per information bit for the normalized Doppler frequency when the power of the pilot channel is 9 dB less than the power of the traffic channel in a DS / CDMA system. .

According to an aspect of the present invention, there is provided a channel estimator for despreading a received pilot channel and estimating a channel from the despread pilot signal; Despread the received traffic channel, demodulate user data contained in the traffic channel by the channel estimated by the first channel estimator from the despread traffic signal, and remove the demodulated data from the despread signal A second channel estimator estimating a channel from the signal from which the demodulated data is removed; And a combiner for coupling the output of the first channel estimator and the output of the second channel estimator.

According to an aspect of the present invention, there is provided a method of estimating a channel by despreading a received pilot channel; (b) despreading the received traffic channel; (c) demodulating user data from the traffic channel despread by the channel estimated in step (a); (d) removing demodulated user data from the despread traffic channel; (e) estimating a channel from the result of step (d); And (f) linearly combining the channels output in the steps (a) and (e), respectively.

In order to achieve the above technical problem, the present invention provides a channel despreader for despreading the received traffic channel; Despread the pilot channel to first estimate the channel, demodulate user data from the traffic channel despread by the primary estimated channel, remove the demodulated user data from the despread traffic channel, and A channel estimator using a pilot and a traffic channel for secondly estimating a channel from the removed traffic channel and combining the first estimated channel and the second estimated channel; And a rake receiver for demodulating user data from the output of the channel despreader and the output of the channel estimator using the pilot and traffic channels.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a channel estimator using a pilot channel and a traffic channel according to the present invention. The channel estimator according to FIG. 1 includes a pilot channel estimator 100, a traffic channel estimator 110, a first multiplier 120, a second multiplier 130, and an adder 140.

The pilot channel estimator 100 estimates a channel using a pilot channel, and the traffic channel estimator 110 estimates a channel using a traffic channel. The first and second multipliers 120 and 130 multiply predetermined values by the estimated values output from the pilot channel estimator 100 and the traffic channel estimator 110, respectively, and the adder 140 adds the multiplied result.

The pilot channel estimator includes a third multiplier 101, a first averager 102, and a first channel estimation filter 103.

The third multiplier 101 multiplies the received data by the Walsh code w _p for the pilot channel, and averages the first multiplier 102 to output the despread signal r _{k, lp} (i). Here, β is a value for normalizing the power of the pilot channel, N is a spreading factor (spreading factor).

The first channel estimation filter 103 estimates a channel from r _{k, lp} (i). As the estimation filter, a filter without time delay is preferable, and an infinite impulse response (IIR) filter having one pole is suitable as an example.

The first channel estimation filter 103 performs a despread signal on the signal received on the lth path for the kth user. In this case, the channel estimation using the pilot channel Is determined as follows.

Here, α is a value optimized in consideration of the Doppler frequency and the SNR of the fading channel. However, since the channel environment cannot be known accurately when receiving data, the value that can be used in all environments is determined and used.

The traffic channel estimator 110 estimates a channel using the traffic channel. The traffic channel estimator 110 includes a fourth multiplier 111, a second averager 112, a temporary data determiner 113, a fifth multiplier 114, and a second estimation filter 115.

The fourth multiplier 111 multiplies the received data by the Walsh code w _t corresponding to the k th user for the traffic channel, and averages it by the second averager 112 to despread the signal. Outputs

The temporary data determiner 113 performs coherent demodulation from the despread signal and the channel value estimated by the first channel estimation filter 103 to perform temporary user data. And coherent demodulation from channel values estimated by corresponding channel estimation filters (not shown) from despread and input signals for each path to determine corresponding temporary usage data. As the temporary data determination unit 113, a normal RAKE receiver is suitable.

The fourth multiplier 114 outputs the signal of the second averager 112. And output from the temporary data determination unit 113 Multiply by to remove the data part contained in the traffic channel. The second estimation filter 115 is a traffic signal from which data is removed by the fifth multiplier 114. Estimate the channel for. Like the first channel estimation filter 103, the second estimation filter 115 is preferably a filter having no time delay. For example, an infinite impulse response filter having one pole is appropriate.

The second estimation filter 115 is a traffic signal from which data is removed for a signal received on an lth path for a kth user. Channel estimation using traffic channels Is determined as follows.

Here, γ may use the same value as the above-described α value as a parameter of the second estimation filter 115.

The adder 140 linearly combines the output of the first channel estimation filter 103 with the output of the second estimation filter 115 to obtain a final channel estimation value. Outputs

Here, a _p and a _t are linear coupling constants, and are determined to minimize the channel estimation square error or maximize the SNR. Or it may be determined from the power ratio of the pilot channel and the traffic channel. However, since the performance change around the optimum linear coupling constant is not sensitive to the change in the channel environment, the peripheral value of the optimal linear coupling constant can be used in all channel environments.

FIG. 2 is a block diagram of a DS / CDMA receiver with a channel estimator shown in FIG. The DS / CDMA receiver according to FIG. 2 includes a traffic channel despreader 200, a channel estimator 202 and a rake receiver 204 using pilot and traffic channels.

The received signal is despread by the traffic channel despreader 200 for each transmission path, and the channel estimator 202 using the pilot and traffic channels performs channel estimation without time delay from the pilot and traffic channels of the received signal. do. The rake receiver 204 distinguishes and combines the despread and channel estimated results for each transmission path for the k-th user. That is, using the multipath time delay in the wireless channel, the same transmitted signal combines the incoming waveform with time difference.

FIG. 3 shows the energy-to-noise ratio (E _b / N ₀ ) required per information bit for the normalized Doppler frequency when the power of the pilot channel is 9 dB less than the power of the traffic channel in a DS / CDMA system. . The channel estimation parameters α and β use the same values in different environments, and the coupling constants a _p and a _t allow the ratio of the two values to be the power ratio of the pilot channel and the traffic channel. FIG. 3 (a) illustrates channel estimation using only a pilot channel, and FIG. 3 (b) illustrates channel estimation using both a pilot channel and a traffic channel. As shown, it can be seen that (E _b / N ₀ ) is smaller in the case of channel estimation using both the pilot channel and the traffic channel than in the case of using only the pilot channel.

According to the present invention, by performing a channel estimation without time delay by using a pilot channel and a traffic channel together, a better performance is obtained at a relatively smaller (E _b / N ₀ ) than when a channel is estimated using only a pilot channel. You can get it. Applying this to the rake receiver can lower the bit error rate. In addition, power estimation requires a channel estimation without delay, which enables more accurate power control, thereby lowering the bit error rate and thus improving system performance.

Claims (9)

A first channel estimator for despreading the received pilot channel and estimating the channel from the despread pilot signal; Despread the received traffic channel, demodulate user data contained in the traffic channel by the channel estimated by the first channel estimator from the despread traffic signal, and remove the demodulated data from the despread signal A second channel estimator estimating a channel from the signal from which the demodulated data is removed; And And a combiner for combining the output of the first channel estimator and the output of the second channel estimator. The method of claim 1, wherein the first channel estimator A pilot channel despreader multiplying and averaging the pilot channel with a predetermined code; And a first infinite impulse response filter for estimating a channel from the despread data. The filter of claim 2, wherein the first infinite impulse response filter The despread signal for the signal received on the l th path for the k th user And, when α is a predetermined parameter, channel estimation by the pilot channel Is the following expression [Equation] Channel estimator using a pilot and traffic channels, characterized in that determined as. The method of claim 1, wherein the second channel estimator A traffic despreader multiplying the traffic channel by a predetermined code and averaging the multiplied value to despread it; A temporary data determiner which demodulates data by the channel estimated by the first channel estimator from the despread signal; A multiplier that multiplies the despread signal by the demodulated data; And And a second infinity impulse response filter for estimating a channel from the output of said multiplier. The filter of claim 4, wherein the second infinite impulse response filter outputs the output signal of the multiplier for the signal received on the lth path for the kth user When γ is a predetermined parameter, channel estimation by the traffic channel Is the following expression [Equation] Channel estimator using a pilot and traffic channels, characterized in that determined as. The method of claim 1, wherein the coupler outputting the first channel estimator for the signal received on the lth path for the kth user; , Outputting the second channel estimation unit And a _p , a _t are the final channel estimates, Then the expression [Equation] A channel estimator using pilot and traffic channels, characterized in that the adder is linearly coupled as shown. The method of claim 6, wherein a _p , a _t is 2. A channel estimator using pilot and traffic channels, characterized in that it is determined to minimize one of channel estimation squared error, maximize signal-to-noise ratio, and power ratio of pilot channel and traffic channel. (a) despreading the received pilot channel to estimate the channel; (b) despreading the received traffic channel; (c) demodulating user data from the traffic channel despread by the channel estimated in step (a); (d) removing demodulated user data from the despread traffic channel; (e) estimating a channel from the result of step (d); And and (f) linearly combining the channels output in the steps (a) and (e), respectively. A channel despreader for despreading the received traffic channel; Despread the pilot channel to first estimate the channel, demodulate user data from the traffic channel despread by the primary estimated channel, remove the demodulated user data from the despread traffic channel, and A channel estimator using a pilot and a traffic channel for secondly estimating a channel from the removed traffic channel and combining the first estimated channel and the second estimated channel; And And a rake receiver for demodulating user data from the output of the channel despreader and the output of the channel estimator using the pilot and traffic channels.