KR20040073126A - Equalizing apparatus and method for orthogonal frequency division multiplexing receiver - Google Patents

Abstract

PURPOSE: An equalizing device of an OFDM(Orthogonal Frequency Division Multiplexing) receiver is provided to firstly compensate for a remaining carrier frequency offset or other phase offset, and to perform a transmission path estimating/updating process, thereby improving equalization performance. CONSTITUTION: A Fourier transform portion(10) converts an input signal of a time area into a frequency area signal. A channel compensator(11) compensate for the signal by using features of an estimated channel. A pilot extractor(100) extracts a pilot sub channel from entire sub channels. A phase offset estimator(101) calculates/estimates a phase difference of the extracted pilot sub channel. A phase offset compensator(102) compensates for a phase of the input signal by using a phase offset of an estimated pilot. A symbol decider(12) decides an original symbol of a transmitter. A channel estimator(13) estimates/updates features of a channel by using the compensated signal and the decided symbol.

Description

EQUALIZING APPARATUS AND METHOD FOR ORTHOGONAL FREQUENCY DIVISION MULTIPLEXING RECEIVER}

The present invention relates to an equalization apparatus and method for an orthogonal frequency division multiplexing receiver, and more particularly, to compensate for a residual carrier frequency offset or other phase offset occurring in a synchronization unit of an orthogonal frequency division multiplexing receiver, and then performs transmission path estimation and update. The present invention relates to an equalization apparatus and method for an orthogonal frequency division multiplexing receiver to improve equalization performance.

In general, the equalizer plays a main role in flattening the uneven signal band according to the characteristics of the transmission path, and processes the residual frequency offset or phase offset generated in the synchronization unit of the receiver. In addition, the orthogonal frequency division multiplexing receiver used in the physical layer of a high-speed wireless LAN, like the receivers of other communication fields, is finally responsible for processing all possible signal distortions except white noise. Equalizer included.

In this case, the equalizer of the orthogonal frequency division multiplexing receiver, unlike other transmission schemes using a time domain equalizer, generally uses a frequency domain equalizer, which divides the transmission band into a large number of subchannels and divides each of the appropriate modulation schemes. This is because the modulation and transmission scheme is suitable for the characteristics of orthogonal frequency division multiplexing. In addition, since the bandwidth of the sub-channel is relatively narrow, such a frequency domain equalizer can be implemented in a simple 1-tap equalizer structure.

1 is a block diagram showing the configuration of an equalizer used in a conventional orthogonal frequency division multiplexing receiver. As shown in FIG. 1, a Fourier transform unit 10 for converting an input signal in a time domain into a frequency domain and an estimated channel ( A channel compensator 11 for compensating an input signal using characteristics of a transmission path, a symbol determiner 12 for determining an original symbol of a transmitter according to a transmission scheme from the compensated signal, and the compensated signal; And a channel estimator 13 for estimating and updating the characteristics of the channel (transmission path) using the determined symbols.

However, since high-speed WLAN uses a wireless transmission path, dynamic signal distortion is larger than that of wired transmission, and carrier synchronization is also relatively difficult because it uses a high frequency of 5 GHz band. Therefore, there is a limit in the performance of processing the distortion of all signals using the equalizer as shown in FIG.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and first compensates for the residual carrier frequency offset or other phase offset occurring in the synchronization unit of the orthogonal frequency division multiplexing receiver, and then performs transmission path estimation and update. It is an object of the present invention to provide an equalization apparatus and method for an orthogonal frequency division multiplexing receiver that can improve equalization performance.

The present invention for achieving the above object, the pilot extractor for extracting a pilot subchannel from the input signal in the frequency domain; A phase offset estimator for calculating and estimating a phase difference between the extracted pilot subchannels; A phase offset compensator for compensating a phase of an input signal by using the estimated phase offset of the pilot; A symbol determination unit that determines a centrifugal ball of the transmitter from the compensated signal; And a channel estimator configured to estimate and update characteristics of the channel using the compensated signal and the determined centrifugal ball.

In addition, the present invention comprises the steps of converting an input signal in the time domain into a signal in the frequency domain to achieve the above object, and compensating the signal in the frequency domain according to the currently estimated channel characteristics; Estimating a phase offset by extracting pilot subchannels from the signal compensated according to the channel characteristic; Compensating for a phase offset with respect to an input signal by the estimated phase offset of the pilot subchannel; And determining a transmission symbol from the phase offset compensated signal, and estimating and updating a characteristic of the channel using the phase compensated signal and symbol.

1 is a block diagram showing the configuration of an equalizer used in a conventional orthogonal frequency division multiplexing receiver.

2 is an exemplary diagram illustrating a subchannel of an orthogonal frequency division multiplexed data symbol.

3 is an exemplary diagram for explaining a phase offset compensation method of a Fourier transform pilot subchannel signal according to the present invention.

4 is an exemplary diagram for explaining a phase offset compensation method of a Fourier transformed data subchannel signal according to the present invention.

5 is a block diagram showing the configuration of an equalizer used in an orthogonal frequency division multiplexing receiver according to the present invention;

FIG. 6 is a block diagram showing a detailed configuration of a phase offset compensator in FIG. 5; FIG.

* Description of the symbols for the main parts of the drawings *

100: pilot extractor 101: phase offset estimator

102: phase offset compensation unit 102a: pilot phase averaging unit

102b: complex conjugate portion 102c: complex waveform generator

102d: delay unit 102e: multiplier

An orthogonal frequency division multiplexed data symbol of a fast WLAN according to the present invention has a pilot subchannel as shown in FIG. That is, orthogonal frequency division multiplexed data symbols of a fast WLAN which are time-frequency transformed by 64-tap Fourier transform have a total of 53 subchannels (-26 to 26) as shown in FIG.

Among them, the subchannel '0' has no transmission signal, and four subchannels (-21, -7, 7, 21) correspond to pilots, and the data subchannels consist of the remaining 48 channels.

Here, since the pilot is a subchannel signal previously promised by the transmitter and the receiver, when the receiver finds a phase of the pilot signal, the pilot may calculate a phase offset of the received signal by comparing the phases with the mutually promised phase. Therefore, the phase of the data subchannel signal using the phase offset of the pilot can be compensated.

FIG. 3 is an exemplary diagram for explaining a phase offset compensation method of a Fourier transform pilot subchannel signal according to the present invention. Since the pilot of FIG. 3 has a phase offset of Θ, the receiver can know that a phase offset of -Θ Multiply by to compensate for the phase of the pilot signal.

FIG. 4 is an exemplary diagram illustrating a phase offset compensation method of a Fourier transformed data subchannel signal according to the present invention. If the pilot subchannel has a phase offset of Θ as shown in FIG. It can be assumed that it has a phase offset. Accordingly, the phase of the data subchannel signal may also be compensated using the phase offset calculated in the pilot subchannel. Here, QPSK is assumed as a modulation method of the data subchannel.

Accordingly, the present invention is to compensate for the phase by obtaining a phase offset of the pilot and applying it to other data subchannels as described above. Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 5 is a block diagram showing the configuration of an equalizer used in an orthogonal frequency division multiplexing receiver according to the present invention. The Fourier transformer 10 converts an input signal in a time domain into a signal in a frequency domain, and an estimated channel ( A channel compensator 11 for compensating a signal using the characteristics of a transmission path), a pilot extractor 100 extracting a pilot subchannel from all subchannels, and a phase difference between the extracted pilot subchannels The phase offset estimator 101, the phase offset compensator 102 for compensating the phase of the input signal using the estimated phase offset of the pilot, and the centrifugal ball of the transmitter And a symbol estimator 12 for determining and a channel estimator 13 for estimating and updating characteristics of a channel (transmission path) by using the compensated signal and the determined symbol.

Hereinafter, referring to the operation of the equalizer configured as described above, first, the input signal in the time domain is converted into a signal in the frequency domain by the Fourier transform unit 10, and the signal in the frequency domain is currently estimated in the channel (transmission path). In the channel compensator 11, the compensation is primarily performed. This process is not different from the operation of the conventional equalizer, but the present invention further includes a process of compensating for the phase offset with respect to the primarily compensated signal, so that the characteristics of the transmission path can be estimated more quickly and accurately.

That is, a pilot subchannel is extracted by the pilot extractor 100, and a phase offset of the pilot subchannel is estimated by the phase offset estimator 101 to compensate for the signal compensated by the channel compensator 11. Phase compensation is performed secondarily in the unit 102, and the signal compensated by the pilot extractor 100, the phase offset estimator 101, and the phase offset compensator 102 as described above is a symbol determination unit 12. ) Is determined to be a specific transmission symbol, and the channel estimator 13 updates the characteristics of the current channel (transmission path) using signals before and after the symbol determiner 12.

Next, FIG. 6 is a block diagram showing a detailed configuration of the phase offset compensator in FIG. 5, wherein a pilot phase average part 102a for obtaining an average of phase offsets for pilot subchannels extracted from an input signal and the estimation A complex conjugate 102b for calculating a complex conjugate (-Θ) of the phase for compensating the average offset (Θ) of the phase, and a complex waveform using the complex conjugate (-Θ) of the calculated phase (cos (- A complex waveform generator 102c for generating Θ) + jsin (-Θ), a delay unit 102d for compensating for a signal for processing time from the pilot extraction to generating a complex waveform for phase offset compensation, and And a multiplier 102e for compensating for the signal R + jI input through the delay unit 102d by the signal generated by the complex waveform generator 102c.

For reference, the real part (O _R ) and the imaginary part (O _I ) of the signal compensated and output through the multiplier (102e) are respectively O _R = Rcos (-Θ)-Isin (-Θ), O _I = Icos (-Θ) + Rsin (-Θ)

As described above, the equalizer according to the present invention obtains an average of phase offsets for four pilots through a phase offset compensator, and calculates a complex conjugate to compensate for the phase offset by multiplying the input signal by using a phase offset compensator. Compensate for the phase offset with respect to the input signal.

As described above, the equalization apparatus and method of the orthogonal frequency division multiplexing receiver of the present invention first compensate for the residual carrier frequency offset or other phase offset occurring in the synchronization unit of the orthogonal frequency division multiplexing receiver, and then performs transmission path estimation and update. By doing so, there is an effect to improve the equalization performance.

In addition, the present invention equalizes a signal in a frequency domain obtained by a Fourier transform, by distinguishing a phase offset generated by a carrier synchronizer of a receiver or for some other reason from signal distortion caused by a transmission path or other reasons. By separately processing, there is an effect to improve the overall equalization performance.

Claims (4)

A pilot extractor for extracting a pilot subchannel from an input signal in a frequency domain; A phase offset estimator for calculating and estimating a phase difference between the extracted pilot subchannels; A phase offset compensator for compensating a phase of an input signal by using the estimated phase offset of the pilot; A symbol determination unit that determines a centrifugal ball of the transmitter from the compensated signal; And a channel estimator configured to estimate and update characteristics of the channel using the compensated signal and the determined centrifugal ball. The method of claim 1, wherein the phase offset compensator comprises: a pilot phase average part that obtains an average of phase offsets of pilot subchannels extracted from an input signal; A complex conjugate part for calculating a complex conjugate of a phase for compensating the average offset of the estimated phase; A complex waveform generator for generating a complex waveform using the complex conjugate of the calculated phase, A delay unit for compensating a signal for processing time from the pilot extraction to generating a complex waveform for phase offset compensation; And a multiplier for compensating for the signal input through the delay unit by the signal generated by the complex waveform generator. Converting an input signal in the time domain into a signal in the frequency domain, and compensating the signal in the frequency domain according to the currently estimated channel characteristics; Estimating a phase offset by extracting pilot subchannels from the signal compensated according to the channel characteristic; Compensating for a phase offset with respect to an input signal by the estimated phase offset of the pilot subchannel; Determining a transmission symbol from the phase offset-compensated signal, and estimating and updating a channel characteristic using the phase-compensated signal and symbol. The method of claim 3, wherein the phase offset compensation for the input signal, Obtaining an average of phase offsets for the pilot subchannels extracted from the input signal; Calculating a complex conjugate of the phase to compensate the average offset of the estimated phase to generate a complex waveform; Delay outputting the input signal until a complex waveform for phase offset compensation is generated; And compensating for the input signal by multiplying the delayed input signal by a complex waveform generated from the signal.