KR20180052003A - Method and Apparatus for Distortion Compensation of Subcarrier in Orthogonal Frequency Division Multiplexing System - Google Patents

Abstract

Disclosed are a method for compensating distortion of a subcarrier by using a single tap equalizer in an OFDM system and an apparatus therefor. The method for compensating distortion of a subcarrier by using a single tap equalizer comprises: extracting a reception pilot signal included in at least one data subcarrier channel; calculating a distortion compensation value for each data subcarrier channel by using a distortion vector value calculated by comparing a predetermined transmission pilot signal with a reception pilot signal; and compensating distortion by applying the distortion compensation value to a data signal.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a subcarrier distortion compensation method using a single tap equalizer in an OFDM system,

The present embodiment relates to a method for compensating distortion of a subcarrier using a single tap equalizer in an OFDM system and an apparatus therefor.

The contents described in this section merely provide background information on the present embodiment and do not constitute the prior art.

The OFDM scheme, which has recently been used as a method for high-speed data transmission in a wired / wireless channel, is a scheme for transmitting data using a multicarrier. The OFDM scheme performs parallel conversion of symbol streams input in series, And is a type of multi carrier modulation (MCM) that modulates and transmits data to a plurality of subcarriers having mutual orthogonality.

The use of the guard interval and the insertion of the CP (Cyclic Prefix) guard interval have been known in the OFDM scheme, thereby further reducing the adverse effect of the system on multipath and delay spread. In addition, the OFDM scheme has been rapidly developed due to various digital signal processing techniques including Fast Fourier Transform (FFT) and Inverse Fast Fourier Transform (IFFT).

The OFDM scheme maintains orthogonality among a plurality of subcarriers and transmits the data, thereby achieving optimal transmission efficiency in high-speed data transmission. In addition, it is characterized by high frequency utilization efficiency and strong characteristics against multi-path fading, thereby achieving optimal transmission efficiency in high-speed data transmission. In addition, since the frequency spectrum is superimposed, frequency use is efficient, frequency selective fading is strong, multipath fading is strong, and the influence of inter symbol interference (ISI, Inter Symbol Interference) is reduced using a guard interval And it is possible to design the equalizer structure in hardware easily and it is advantageous to be strong against the impulse noise, so that it is being utilized in the communication system structure.

The multiple access scheme based on the OFDM scheme is an OFDMA scheme. The OFDMA scheme is a scheme in which a plurality of users, that is, a plurality of terminals divide and use subcarriers in one OFDM symbol.

Meanwhile, in a broadband wireless communication system, a transmission signal transmitted by a transmitter is distorted while passing through a wireless channel, and a receiver receives a distorted transmission signal. Also, a problem may occur such that a transmission signal is lost before being transmitted to a receiver due to a problem on a channel or the like, or a transmission signal is distorted and received until a transmission signal of the transmitter is transmitted to the receiver. Accordingly, in the broadband wireless communication system, various alternatives for improving the reception performance of the receiver have been researched and developed.

In this embodiment, a received pilot signal included in at least one data subcarrier channel is extracted, and a distortion compensation value for each data subcarrier channel is calculated using a distortion vector value calculated by comparing a predetermined transmission pilot signal with a received pilot signal And compensates for distortion by applying a distortion compensation value to the data signal, and a device for the same. The present invention also provides a method of compensating distortion of a subcarrier using a single tap equalizer.

According to an aspect of the present invention, there is provided an apparatus for compensating for distortion of a data subcarrier channel included in an Orthogonal Frequency Division Multiplexing (OFDM) symbol, comprising: a pilot signal extractor for extracting a pilot signal from each of at least one data subcarrier channel; An extraction unit; A channel estimator for estimating a channel by calculating a distortion vector value of at least one received pilot signal using a predetermined transmission pilot value; A compensation value calculation unit for calculating a distortion compensation value for each of at least one data subcarrier channel using the distortion vector value; A compensation value processor for transmitting the distortion compensation value to each of the at least one data sub-carrier channel; And a distortion compensator for compensating distortion of the data signal for each of the at least one data subcarrier channel based on the distortion compensation value.

According to another aspect of the present invention, there is provided a method of compensating for distortion of a data subcarrier channel included in an OFDM symbol, the method comprising: extracting a pilot signal from each of at least one data subcarrier channel; A pilot signal extraction process; A channel estimation process of calculating a distortion vector value for at least one received pilot signal using a predetermined transmission pilot value to estimate a channel; Calculating a distortion compensation value for each of at least one data sub-carrier channel using the distortion vector value; A compensation value processing step of transmitting the distortion compensation value on each of the at least one data sub-carrier channel; And a distortion compensating step of compensating for a distortion of a data signal for each of the at least one data subcarrier channel based on the distortion compensation value. The method of compensating distortion of a subcarrier using a single tap equalizer.

As described above, according to the present embodiment, distortion of the data signal can be significantly improved.

In addition, distortion of a data signal of a subcarrier channel can be accurately compensated by using a distortion compensation apparatus, and high-quality OFDM communication performance can be guaranteed.

Further, the distortion compensating apparatus compensates the distortion by using the pilot signal for all the subcarrier channels, thereby correcting the distortion accurately.

In addition, the distortion compensation apparatus has an effect of minimizing a calculation amount for compensating for distortion.

1 is a block diagram schematically showing an OFDM-based wireless communication system according to the present embodiment.
2 is a block diagram schematically showing an equalizer included in a receiver according to the present embodiment.
3 is a flowchart for explaining a method of compensating distortion of a subcarrier channel in an equalizer according to the present embodiment.
FIGS. 4 and 5 are views schematically illustrating an operation of compensating distortion of a subcarrier channel according to the present embodiment.
FIG. 6 is a graph for explaining a distortion compensation operation in 16 equalizer-based equalizers according to the present embodiment.
7 is an exemplary diagram for schematically explaining the operation of the equalizer for compensating the distortion of the subcarrier channel according to the present embodiment.
8 is an exemplary diagram illustrating an equalizer for compensating distortion of a subcarrier channel according to the present embodiment.
9 is a diagram illustrating an example of a pilot signal for compensating for distortion of a subcarrier channel according to an embodiment of the present invention.
10 is an exemplary diagram showing a signal in which distortion is compensated in the equalizer according to the present embodiment.

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing an OFDM-based wireless communication system according to the present embodiment.

An orthogonal frequency division multiplexing (OFDM) based wireless communication system 100 according to the present embodiment includes an OFDM transmitter 110 for transmitting wideband data and an OFDM receiver 120 for receiving wideband data. The OFDM receiver 120 includes an RF communication unit 130, an ADC 140, an FFT 150, an equalizer 160 and a demodulator 170.

The OFDM transmitter 110 generates a plurality of modulated data and maps the modulated data to a subcarrier channel. The OFDM transmitter 110 sets a part of subcarrier channels as a pilot channel, and inserts a pilot signal into the pilot channel. Here, the pilot signal does not include actual data but refers to a signal inserted for channel estimation, synchronization, information acquisition, distortion compensation, and the like.

The OFDM transmitter 110 performs inverse fast Fourier transform (IFFT) operation on a signal included in a subcarrier channel to output sample data in a time domain and adds a CP (Cyclic Prefix) to the sample data to generate an OFDM symbol And then transmits the wideband data obtained by converting the OFDM symbol generated to the analog signal to the OFDM receiver 120.

The OFDM transmitter 110 transmits a data signal including a transmission pilot signal to at least one data subcarrier channel. Here, the transmission pilot signal may be a signal having the same value, but is not limited thereto.

The OFDM receiver 120 receives broadband data from the OFDM transmitter 110.

The RF communication unit 130 receives the wideband data transmitted from the OFDM transmitter 110. Here, the wideband data is received in a form in which a noise component is added via a multipath channel. The RF communication unit 130 outputs the analog signal obtained by downconverting the received wideband data to an intermediate frequency (IF) band or an area near the DC to the ADC 140.

The ADC 140 samples the analog signal and converts it into a digital signal. In other words, the ADC 140 acquires the analog signal output from the RF communication unit 130 and outputs the digital-converted sample data to the FFT 150. Here, the sample data may be output to the FFT 150 via a guard interval remover (not shown) that removes a CP (Cyclic Prefix).

The FFT 150 performs an FFT (Fast Fourier Transform) operation on the sample data to generate OFDM symbols in the frequency domain.

The equalizer 160 is located between the FFT 150 and the demodulator 170 and compensates for distortion of data included in the subcarrier channel output from the output terminal of the FFT 150.

The equalizer 160 according to the present embodiment extracts a received pilot signal included in at least one data subcarrier channel. The equalizer 160 compares the preamble transmission pilot signal with the received pilot signal to calculate a distortion vector value, and calculates a distortion compensation value for each data subcarrier channel using the calculated distortion vector value.

The equalizer 160 applies the calculated distortion compensation value to the data signal to generate a data signal whose distortion is compensated and transmits the data signal to the demodulator 179. The operation of compensating the distortion in the equalizer 160 will be described in detail in FIG.

The demodulator 170 demodulates the data signal in which the distortion is compensated in the equalizer 160 by a modulation scheme, for example, a Quadrature Amplitude Modulation (QAM) scheme used in the OFDM transmitter 110.

2 is a block diagram schematically showing an equalizer included in a receiver according to the present embodiment.

The equalizer 160 according to the present embodiment includes a pilot signal extractor 210, a channel estimator 220, a compensation value calculator 230, a compensation value processor 240, and a distortion compensator 250 . Here, the equalizer 160 may be an equalizer included in the OFDM receiver 120, but is not limited thereto. The equalizer 160 may be provided inside or outside the OFDM receiver 120 to compensate for distortion Compensation device.

The pilot signal extracting unit 210 extracts a received pilot signal on a data subcarrier channel. In other words, the pilot signal extracting unit 210 acquires an I / Q signal from a pilot channel included in the OFDM symbol and extracts a received pilot signal corresponding to a predetermined sequence. Herein, the received pilot signal means a signal received from the OFDM transmitter 110 on the transmission pilot signal inserted in the subcarrier channel. The received pilot signals are received in the order in which the transmitted pilot signals are inserted, and each received pilot signal includes an I / Q signal. The received pilot signal is distorted in the process of being received from the OFDM transmitter 110. [ That is, the received pilot signal includes a distortion signal.

The pilot signal extracting unit 210 may extract k received pilot signals of k (1? K? M, k is a natural number and m is the number of subcarrier channels) for at least one data subcarrier channel. Since a peak of a signal occurs when there is a received pilot signal in all the data subcarrier channels, it is possible to obtain a signal of k (1? K? M, k is a natural number and m is the number of subcarrier channels) among at least one data subcarrier channel And extracts the received pilot signal included therein. For example, the pilot signal extracting unit 210 may extract a transmission pilot signal transmitted in fourteen times for 128 data subcarrier channels as a received pilot signal.

The channel estimator 220 estimates the distortion state of the data subcarrier channel based on the received pilot signal.

The channel estimator 220 calculates a distortion vector value for the received pilot signal using a predetermined transmission pilot value and estimates a distortion state of the data subcarrier channel based on the distortion vector value. In more detail, the channel estimator 220 compares the transmit pilot value of the transmit pilot signal transmitted from the OFDM transmitter 110 with the receive pilot value of the receive pilot signal, and calculates a distortion vector value of the receive pilot signal. Here, the transmission pilot signals of each of the at least one data subcarrier channel may have the same value, but the present invention is not limited thereto. The pilot signal may be a pilot signal combined with values of + (Positive), - (Negative) . For example, the transmit pilot signal of each data subcarrier channel has the same transmit pilot value as a value of '1', and the channel estimator 220 calculates a value of a transmit pilot signal having a value of '1' The distortion vector value can be calculated. On the other hand, the transmission pilot signal of each data subcarrier channel is compared with the value of the reception pilot signal having a value of '1', '-1', '1',. Value can be calculated.

The channel estimator 220 preferably calculates a distortion vector value using k (1? K? M, k is a natural number and m is the number of subcarrier channels) extracted for at least one data subcarrier channel But is not limited thereto. For example, the channel estimator 220 may calculate a distortion vector value using 14 received pilot signals for 128 data subcarrier channels.

The channel estimator 220 may calculate an average of distortion values of k received pilot signals for at least one data subcarrier channel as a distortion vector value.

The compensation value calculator 230 calculates the distortion compensation value for compensating for the signal distortion of the data signal for each data subcarrier channel using the distortion vector value. Here, the compensation value calculation unit 230 calculates the inverse value of the distortion vector value to calculate the distortion compensation value, but is not limited thereto.

The compensation value calculation unit 230 sets a processing time for calculating the distortion compensation value. In other words, the compensation value calculator 230 sets the processing time to be less than the Channel Varying Time of at least one data subcarrier channel.

The compensation value calculator 230 calculates a distortion compensation value for each data subcarrier channel, and each distortion compensation value may include a first compensation value for the I signal and a second compensation value for the Q signal.

The compensation value processing unit 240 transmits the distortion compensation values on the respective data subcarrier channels. The compensation value processor 240 transmits the distortion compensation value to each of the at least one data subcarrier channel.

The compensation value processor 240 may separately transmit the first compensation value and the second compensation value included in the distortion compensation value, but the present invention is not limited thereto. The compensation value processor 240 may be configured to compensate the distortion compensator 250 for each of the data sub- It is possible to transmit a distortion compensation value for the channel.

The distortion compensating unit 250 compensates for the signal distortion of the data signal for each of the data subcarrier channels based on the distortion compensation value received from the compensation value processing unit 240. [

The distortion compensating unit 250 receives a first data signal including a distortion signal from the OFDM transmitter 110 and applies a distortion compensation value to the first data signal to generate a second data signal in which the distortion signal is compensated.

The distortion compensating unit 250 may generate the second data signal by applying a first compensation value and a second compensation value included in the distortion compensation value to each of the I / Q signals included in the first data signal. For example, the distortion compensator 250 may generate an I signal of the second data signal by applying a first compensation value to the I signal of the first data signal and applying a second compensation value to the Q signal of the first data signal. do. The distortion compensator 250 applies a second compensation value to the I signal of the first data signal and applies a first compensation value to the Q signal of the first data signal to generate a Q signal of the second data signal.

The distortion compensating unit 250 transmits the second data signal to the demodulator 170 so that the second data signal is demodulated.

3 is a flowchart for explaining a method of compensating distortion of a subcarrier channel in an equalizer according to the present embodiment.

The equalizer 160 extracts a received pilot signal for each data subcarrier channel (S310). The equalizer 160 acquires an I / Q signal from a pilot channel included in an OFDM symbol and extracts a received pilot signal corresponding to a predetermined sequence. Herein, the received pilot signal means a signal received from the OFDM transmitter 110 on the transmission pilot signal inserted in the subcarrier channel.

The equalizer 160 extracts the received pilot signals of k (1? K? M, k is a natural number, and m is the number of subcarrier channels) for at least one data subcarrier channel.

The equalizer 160 calculates a distortion vector value for the received pilot signal to estimate a distortion state of the channel (S320). The equalizer 160 calculates a distortion vector value for the received pilot signal using a predetermined transmission pilot value and estimates a distortion state of the data subcarrier channel based on the distortion vector value. In other words, the equalizer 160 compares the transmit pilot value of the transmit pilot signal transmitted from the OFDM transmitter 110 with the receive pilot value of the receive pilot signal to calculate a distortion vector value of the receive pilot signal. Here, the transmission pilot signals of at least one data subcarrier channel may have the same transmission pilot value, but are not limited thereto. For example, the transmit pilot signal of each of the at least one data subcarrier channel may be a pilot signal combined with values of + (Positive), - (Negative), and 0 (Zero).

The equalizer 160 calculates a distortion compensation value for each data subcarrier channel using the distortion vector value (S330). The equalizer 160 calculates the distortion compensation value for compensating for the signal distortion of the data signal for each data subcarrier channel using the distortion vector value. Here, the equalizer 160 may calculate the distortion compensation value by calculating the inverse value of the distortion vector value.

The equalizer 160 compensates for the distortion of the data signal by applying a distortion compensation value to the data signal for each data subcarrier channel (S340). The equalizer 160 receives a first data signal including a distortion signal from the OFDM transmitter 110 and applies a distortion compensation value to the first data signal to generate a second data signal in which the distortion signal is compensated.

4 is an exemplary diagram schematically illustrating an operation of compensating distortion of a subcarrier channel according to the present embodiment.

Hereinafter, an operation for compensating the distortion of the subcarrier channel in the OFDM-based wireless communication system 100 will be described with reference to FIG.

In the OFDM-based wireless communication system 100, it is assumed that the OFDM signal is affected by the frequency selective filter and the bandwidth of the subcarrier is designed to be smaller than the coherence bandwidth of the data subcarrier channel. Here, the equalizer 160 included in the wireless communication system 100 calculates the frequency flat fading of each of the sub-carrier channels represented by one complex multiplication, and the equalization for the distorted signal is And is processed using the same one-tap for each sub-carrier channel.

The wireless communication system 100 according to the present embodiment performs OFDM equalization in the frequency domain. 4, inverse Fast Fourier Transform (IFFT) is performed on the subcarrier vector X in the frequency domain with the data signal x in the time domain through the OFDM transmitter 110 (x = IFFT (X).

An impulse response vector h of the data subcarrier channel, that is, a distortion signal, is added in the process of transmitting the data signal x from the OFDM transmitter 110 to the OFDM receiver 120. Therefore, the OFDM receiver 120 receives the data signal y convolved with the data signal x and the distortion signal h (y = x * h).

The OFDM receiver 120 performs Fast Fourier Transform (FFT) on the data signal y to generate a first data signal Y. Here, the first data signal Y is Y = FFT (y) = X · H, and H = FFT (h). The first data signal Y is generated by applying Element Wise-Multiplication ().

The equalizer 160 included in the OFDM receiver 120 extracts the pilot signal from the first data signal Y and calculates the distortion signal H using the pilot signal to estimate the distortion of the subcarrier channel.

The equalizer 160 applies the inverse of the distortion signal H to the first data Y to compensate for the distortion of each subcarrier channel. In other words, the equalizer 160 processes Z = Y / H = X H / H to generate the second data signal Z whose distortion is compensated. Here, the second data signal Z may be generated by applying an Elements Wise-Division (/).

5 is an exemplary diagram schematically illustrating an operation of compensating distortion of a subcarrier channel according to the present embodiment.

5 (a) shows transmission data X _n for each of at least one subcarrier channel. The transmission data X _n is IFFT-transformed by the OFDM transmitter 110 and is added to the impulse response vector h _n of the data subcarrier channel in the process of being transmitted to the OFDM receiver 120. Therefore, the OFDM receiver 120 receives the data signal y _n (y = x * h) in which the data signal x _n and the distortion signal h _n are convolved.

5B shows a first data signal Y obtained by FFT-transforming the data signal x received from the OFDM transmitter 110 in the OFDM receiver 110. In FIG. The first data signal Y _n includes a pilot signal P _n and a general data signal D _n .

5C shows a distortion signal H _n extracted by extracting the pilot signal P _n from the first data signal Y _n and using the pilot signal P _n . 5 (d) shows the distortion compensation value (/ H _n ) calculated by inverse wavelet processing, that is, Elements Wise-Division (/) processing, on the extracted distortion signal H _n . FIG. 5E shows the second data (X ' _n ) in which the distortion is compensated by applying the distortion compensation value / H _n to the first data signal Y. FIG.

FIG. 6 is a graph for explaining a distortion compensation operation in 16 equalizer-based equalizers according to the present embodiment.

6 (a), 6 (b) and 6 (c) show graphs for explaining an operation of calculating a distortion vector and a distortion compensation value using a received pilot signal including a transmission pilot signal and a distortion signal, (D), (e), and (f) show graphs for explaining an operation of outputting a data signal whose distortion is compensated by applying a distortion compensation value to an input actual data signal.

6A shows a pilot signal having a size of 1 transmitted in each data subcarrier channel (16 channels) in the OFDM transmitter 110. In FIG.

6 (b) shows a pilot signal including the distortion signal received by the equalizer 160. In FIG. Here, the equalizer 160 extracts the distortion vector H from the received pilot signal.

6 (c) shows the distortion compensation value / H calculated using the distortion vector H extracted by the equalizer 160. Here, the equalizer 160 preferably calculates the inverse of the distortion vector H to calculate the distortion compensation value / H, but is not limited thereto.

FIG. 6 (d) shows a data signal transmitted in each of the data subcarrier channels (16 channels) in the OFDM transmitter 110.

6 (e) shows a data signal including the distortion signal received by the equalizer 160. In FIG. FIG. 6F shows a data signal in which the distortion is compensated by applying the distortion compensation value / H shown in FIG. 6C to the received data signal.

Although the Figure 6, the substrate to compensate for the distortion in the 16 sub-carriers based on the channel equalizer is be possible to apply all the equalizer of the channel based not, 2 ⁿ pieces (n> a natural number of 1) is not limited thereto.

7 is an exemplary diagram for schematically explaining the operation of the equalizer for compensating the distortion of the subcarrier channel according to the present embodiment.

As shown in FIG. 7, the equalizer 110 extracts a received pilot signal from a first data signal received through 128 subcarrier channels. Here, the received pilot signal includes [h ₀ ', h ₁ ', ..., h ₁₂₇ '] and the like as a vector including a distortion signal in a transmission pilot signal of size 1. Here, the received pilot signal is extracted from each of the 128 subcarrier channels. However, the present invention is not limited thereto and may be a received pilot signal extracted from some of the 128 subcarrier channels.

The equalizer 110 extracts the distortion vector H from the received pilot signal and calculates the distortion compensation value H ^-1 using the distortion vector H. [ Here, the equalizer 110 may calculate the distortion vector H by receiving the received pilot signal M times (2? M, M is a natural number) to minimize the error (error) of the distortion vector H. For example, the equalizer 110 may calculate the distortion vector H using the average value of the movement of the window set to M, and the distortion vector H may be calculated as [h ₀ , h ₁ , ..., h ₁₂₇ ], and the like.

The equalizer 110 performs reciprocal processing on the calculated distortion vector H to calculate a distortion compensation value H ^-1 . The distortion compensation value (H ^-1 ) may include [r ₀ , r ₁ , ..., r ₁₂₇ ] and the like. The equalizer 110 calculates a distortion compensation value (H ^-1 ) including a first compensation value and a second compensation value for compensating the I / Q signal of the data signal.

The equalizer 110 applies the distortion compensation value (H ^-1 ) to the data signal y _n including the distortion signal to compensate for the distortion. The equalizer 110 applies a first compensation value to the I signal of the data signal y _n including the distortion signal and applies a second compensation value to the Q signal to generate an I signal of the distortion compensated data signal do. The equalizer 110 applies a second compensation value to the I signal of the data signal y _n including the distortion signal and applies a first compensation value to the Q signal to generate a Q signal of the distortion compensated data signal .

8 is an exemplary diagram illustrating an equalizer for compensating distortion of a subcarrier channel according to the present embodiment.

Hereinafter, the operation of the equalizer 110 will be described with reference to FIG. 8, and some descriptions overlapping with those shown in FIG. 2 or 7 may be omitted.

(1) The equalizer 160 calculates a distortion vector based on the received pilot signal. The distortion vector can be calculated as r _n = (a _n , b _n ) = a _n + _j b _n = h _n '.

(2) If the distortion vector is transformed into a polar coordinate system, h _n '= (h _{i n} , hq _n ) = h _{i n} + jhq _n = M _n (h i _n M _n ^-1 + jhq _n M _n ^-1 ).

(3) The equalizer 160 calculates the distortion compensation value using the distortion vector. The distortion compensation value is r _n '= (h _n ') ^-1 = M _n ^-1 (h _{i n} M _n ^-1 + jhq _n M _n ^{- 1} ), and M _n ^-1 represents 1 / (square root of I _n ² + Q _n ² ).

(4) The equalizer 160 compensates the distortion of the data signal by applying the distortion compensation value r _n 'to the data signal y _n . The distortion-compensated data (z _n ) is z _n = y _n r _n '= (I _n , Q _n ) (a _n ', b _n ') = (I _n a _n ' - Q _n b _n ', I _n b _n ' + Q _n a _n ' Can be displayed. 8, the equalizer 110 applies a first compensation value 830 to the I signal 810 of the data signal y _n including the distortion signal, the second compensation value 840 is applied to the Q signal 820 of the distortion compensated data signal y _n , and the difference between the two values to which each compensation value is applied is calculated to obtain the I 'signal 850 of the distortion compensated data signal .

Also, the equalizer 110 is a second compensation value data signal (y _n) comprises applying (840), and a distortion signal to the I signal 810 of the data signal (y _n) comprising a distortion signal Q A first compensation value 830 is applied to the signal 820 and the sum of the two values to which each compensation value is applied is generated to generate the Q 'signal 860 of the distortion compensated data signal.

9 is a diagram illustrating an example of a pilot signal for compensating for distortion of a subcarrier channel according to an embodiment of the present invention.

The pilot signal transmitted from the OFDM transmitter 110 according to the present embodiment is allocated to a time domain of one OFDM symbol when 255 OFDM symbols are transmitted.

For example, as shown in FIG. 9, the OFDM transmitter 110 divides the pilot signals for 128 subcarrier channels into 2 time regions in each of 14 OFDM symbols. Here, the time domain including the pilot signal may be different for each OFDM symbol.

When the OFDM transmitter 110 transmits all pilot signals for 128 subcarrier channels in one OFDM symbol and transmits the pilot signals, a peak of a signal occurs and distortion occurs. Therefore, pilot signals of 128 subcarrier channels are transmitted to a predetermined (For example, 14).

The equalizer 160 according to the present embodiment extracts a distortion vector H of the channel based on the pilot signal received via the subcarrier channel and equalizes the data signal based on the distortion vector H. [ Here, the distortion vector H may include phase information, size information, and the like of a signal carried on each of the subcarrier channels.

10 is an exemplary diagram showing a signal in which distortion is compensated in the equalizer according to the present embodiment.

10A is a graph showing a signal of a subcarrier channel obtained by the equalizer 160 from the FFT 150. FIG. That is, the graph of FIG. 10 (a) shows a signal of a subcarrier channel whose amplitude and phase are distorted.

10B is a graph showing a signal of a subcarrier channel outputted by correcting the distortion in the equalizer 160. In FIG. That is, the graph of FIG. 10 (b) shows a signal of a subcarrier channel whose distortion is compensated by applying a distortion compensation value calculated based on the amplitude and phase of the pilot signal.

The foregoing description is merely illustrative of the technical idea of the present embodiment, and various modifications and changes may be made to those skilled in the art without departing from the essential characteristics of the embodiments. Therefore, the present embodiments are to be construed as illustrative rather than restrictive, and the scope of the technical idea of the present embodiment is not limited by these embodiments. The scope of protection of the present embodiment should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

110: OFDM transmitter 120: OFDM receiver
130: RF communication unit 140: ADC
150: FFT 160: equalizer
170: Demodulator
210: Pilot signal extractor 220: Channel estimator
230: compensation value calculating section 240: compensation value processing section
250:

Claims (15)

1. An apparatus for compensating for distortion of a data subcarrier channel included in an Orthogonal Frequency Division Multiplexing (OFDM) symbol,
A pilot signal extracting unit for extracting a received pilot signal from each of at least one data subcarrier channel;
A channel estimator for estimating a channel by calculating a distortion vector value of at least one received pilot signal using a predetermined transmission pilot value;
A compensation value calculation unit for calculating a distortion compensation value for each of at least one data subcarrier channel using the distortion vector value;
A compensation value processor for transmitting the distortion compensation value to each of the at least one data sub-carrier channel; And
A distortion compensating unit for compensating for distortion of a data signal for each of at least one data subcarrier channel based on the distortion compensation value,
The distortion compensating apparatus comprising: The method according to claim 1,
Wherein the channel estimator comprises:
The OFDM transmitter calculates a distortion vector value of the received pilot signal by comparing a transmitted pilot value of a transmitted pilot signal transmitted through a data subcarrier channel with a received pilot value of the received pilot signal, Wherein the transmission pilot signal is a signal including the same transmission pilot value or a transmission pilot value combined with at least one value of + (Positive), - (Negative), and 0 (Zero) . The method according to claim 1,
Wherein the channel estimator comprises:
Wherein the distortion vector calculator calculates the distortion vector value using the received pilot signal received every k (1? K? M, k is a natural number and m is a number of subcarrier channels) for each of the at least one data subcarrier channel Device. The method of claim 3,
Wherein the channel estimator comprises:
And calculates an average of k distortion values for each data subcarrier channel as the distortion vector value. The method according to claim 1,
The compensation value calculation unit calculates,
And calculates the inverse of the distortion vector value to calculate the distortion compensation value. The method according to claim 1,
The compensation value calculation unit calculates,
A processing time for calculating the distortion compensation value is set,
Wherein the processing time is set to be smaller than a channel variation time of a data subcarrier channel. The method according to claim 1,
The compensation value calculation unit calculates,
Wherein the distortion compensating unit calculates the distortion compensation value including a first compensation value for compensating the I signal of the data signal and a second compensation value for compensating the Q signal of the data signal. 8. The method of claim 7,
Wherein the distortion compensating unit comprises:
Applying the first compensation value and the second compensation value to an I / Q signal included in the data signal to generate a distortion-compensated data signal, and transmitting the distorted compensated data signal to a demodulator And a distortion compensating device. 9. The method of claim 8,
Wherein the distortion compensating unit comprises:
Applying a first compensation value to the I signal of the data signal and applying a second compensation value to the Q signal of the data signal to generate an I signal of the compensated data signal, 2 compensation value and applies a first compensation value to the Q signal of the data signal to generate a Q signal of the distortion compensated data signal. A method for compensating for distortion of a data subcarrier channel included in an Orthogonal Frequency Division Multiplexing (OFDM) symbol,
A pilot signal extracting step of extracting a received pilot signal from each of at least one data subcarrier channel;
A channel estimation process of calculating a distortion vector value for at least one received pilot signal using a predetermined transmission pilot value to estimate a channel;
Calculating a distortion compensation value for each of at least one data sub-carrier channel using the distortion vector value;
A compensation value processing step of transmitting the distortion compensation value on each of the at least one data sub-carrier channel; And
A distortion compensation process for compensating distortion of a data signal for each of at least one data subcarrier channel based on the distortion compensation value;
And compensating for distortion of the subcarrier using the single tap equalizer. 11. The method of claim 10,
The channel estimation process includes:
The OFDM transmitter compares a transmitted pilot value of a transmitted pilot signal transmitted through a data subcarrier channel with a received pilot value of the received pilot signal to calculate a distortion vector value of the received pilot signal,
Wherein the transmit pilot signal of each of the at least one data subcarrier channel includes a transmit pilot value that is the same as or equal to at least one of positive (+), negative (-), and zero Wherein the first and second subcarriers are equal in magnitude to each other. 11. The method of claim 10,
The compensation value calculation step may include:
And calculating the inverse of the distortion vector value to calculate the distortion compensation value. 11. The method of claim 10,
The compensation value calculation step may include:
And calculating a distortion compensation value including a first compensation value for compensating the I signal of the data signal and a second compensation value for compensating the Q signal of the data signal. Distortion compensation method. 14. The method of claim 13,
The distortion compensation process includes:
Applying the first compensation value and the second compensation value to an I / Q signal included in the data signal to generate a distortion-compensated data signal, and transmitting the distorted compensated data signal to a demodulator A method for compensating distortion of a subcarrier using a single tap equalizer. 15. The method of claim 14,
The distortion compensation process includes:
Applying a first compensation value to the I signal of the data signal and applying a second compensation value to the Q signal of the data signal to generate an I signal of the compensated data signal, 2 compensation value and applies a first compensation value to the Q signal of the data signal to generate a Q signal of the distortion compensated data signal.

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