KR101748983B1 - Device and Method for Estimating Channel in FBMC System Having Multiple Antennas - Google Patents

Abstract

An apparatus and method for channel estimation in an FBMC system having multiple antennas are disclosed. The apparatus includes a reference symbol extracting unit for extracting a reference symbol for each antenna; A channel coefficient estimator for estimating a channel coefficient of resource elements in which reference symbols are arranged using the extracted reference symbol information; An interpolation unit for estimating channel coefficients of resource elements in which data symbols are arranged using interpolation by using channel coefficients of resource elements in which the reference symbols estimated by the channel coefficient estimating unit are arranged; A total interference amount calculation unit for calculating an interference amount by surrounding reference symbols for each antenna using the impulse response of the FMBC filter to calculate a total interference amount; And a channel coefficient updating unit for updating the channel coefficient by subtracting the total interference amount calculated by the total interference amount calculation unit from the channel coefficients estimated by the interpolation unit and the channel coefficient estimation unit, And is repeated based on preset conditions. According to the disclosed apparatus and method, it is possible to perform relatively accurate channel estimation in consideration of inherent interference occurring in the FBMC system.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to an apparatus and a method for estimating a channel in an FBMC system having multiple antennas,

Embodiments of the present invention relate to a channel estimation apparatus and method, and more particularly, to a channel estimation apparatus and method in an FBMC system having multiple antennas.

Since the interference between the time symbol and the subcarrier does not occur in the Orthogonal Frequency Division Multiplexing (OFDM) system, the position of the resource element in which the reference symbol is disposed in the arrangement of the reference symbol is different from that of the symbol The reference symbols are arranged by a relatively simple principle not to arrange the reference symbols.

However, in the case of the FBMC / QAM system, since there is interference between the time symbol and the subcarrier, it is necessary to arrange the reference symbol considering the interference in the arrangement of the reference symbol. Also, in the FBMC / QAM system having multiple antennas, an interference effect is placed in resource elements that are not arranged due to interference between time symbols and subcarriers of the FBMC / QAM system. Thus, the reference symbol is a reference symbol Or interference from data symbols. Therefore, when the reference symbol arrangement such as the conventional art is used in an FBMC / QAM system having multiple antennas, a channel estimation performance degradation due to interference occurs.

An aspect of the present invention is to provide an apparatus and method for estimating an accurate channel considering interference in an FBMC system using multiple antennas.

According to an aspect of the present invention, there is provided an antenna apparatus comprising: a reference symbol extracting unit for extracting a reference symbol for each antenna; A first channel coefficient estimator for estimating a channel coefficient of resource elements in which reference symbols are arranged using the extracted reference symbol information; A second channel coefficient estimator for estimating a channel coefficient of resource elements in which data symbols are allocated using channel coefficients of resource elements in which the reference symbol estimated by the channel coefficient estimator is arranged; A total interference amount calculation unit for calculating an interference amount by surrounding reference symbols for each antenna using the impulse response of the FMBC filter to calculate a total interference amount; And a channel coefficient updating unit for updating the channel coefficient by subtracting the total interference amount calculated by the total interference amount calculation unit from the channel coefficients estimated by the interpolation unit and the channel coefficient estimation unit, A channel estimation apparatus in an FBMC system having multiple antennas that are repeated based on preset conditions is provided.

The total interference amount operation unit sums the interference amount due to neighboring reference symbols for each resource element coordinate using the impulse response of the FBMC filter.

The total interference amount calculation unit estimates channel information on a specific time axis of the resource element map, and calculates a total interference amount using the channel information.

The total interference amount calculation unit calculates the total interference amount as shown in the following equation.

는 레퍼런시 심볼이 실린 위치 정보를 위미하고,

는 해당 위치에서의 레퍼런스 심볼 값을 의미하며,

는 특정 시간축 k에서의 채널 정보를 의미하며, g[k]는 FBMC에서 사용하는 필터 응답을 의미함. Where m and n are the frequency and time index of the transmission signal, i is the antenna index, N _T is the total number of antennas, p and q are the resource element coordinates,

The position information containing the reference symbol is favored,

Denotes a reference symbol value at the corresponding position,

Denotes channel information at a specific time axis k, and g [k] denotes a filter response used in the FBMC.

The channel update of the first channel coefficient update unit is performed according to the following equation.

은 리소스 엘리먼트 p,q 좌표에서의 갱신된 채널 계수를 의미하고

는 갱신전 리소스 엘리먼트 p,q 좌표에서의 채널 계수를 의미하며,

는 리소스 엘리먼트 p,q 좌표에서의 총 간섭량을 의미함. In the above equation,

Denotes an updated channel coefficient in the resource element p and q coordinates

Denotes a channel coefficient in the p and q coordinates of the resource element before the update,

Is the total amount of interference in the p and q coordinates of the resource element.

The channel information on the specific time axis of the resource element map is estimated as the following equation.

The updating of the channel coefficient is repeated until the difference between the previous channel coefficient and the current channel coefficient becomes equal to or less than a preset threshold value.

The updating of the channel coefficient is performed until a preset number of repetitions is reached.

The second channel coefficient estimator estimates a channel coefficient of resource elements in which the data symbols are arranged using interpolation.

According to still another aspect of the present invention, there is provided a method of generating a reference symbol, comprising: (a) extracting a reference symbol for each antenna; (B) estimating channel coefficients of resource elements in which reference symbols are arranged using the extracted reference symbol information; (C) estimating a channel coefficient of resource elements in which data symbols are arranged using the channel coefficients of the resource elements in which the reference symbol estimated by the channel coefficient estimator is arranged; (D) calculating an interference amount by neighboring reference symbols for each antenna using an impulse response of the FMBC filter to calculate a total interference amount; And a step (e) of subtracting a total interference amount calculated in the total interference amount calculation unit from channel coefficients estimated by the interpolation unit and the channel coefficient estimation unit to update a channel coefficient, wherein the channel coefficient The update is provided by a channel estimation method in an FBMC system having multiple antennas that are repeated based on preset conditions.

According to the present invention, it is possible to perform relatively accurate channel estimation in consideration of inherent interference occurring in the FBMC system.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a diagram showing an example of arranging reference symbols of multiple antennas in a general OFDM system; Fig.
2 is a view for explaining interference that occurs when a MIMO FBMC is used;
FIG. 3 is a diagram for more specifically explaining interference that occurs when an FBMC is used; FIG.
4 shows an example of an impulse response for each time and frequency of an FBMC filter.
5 is a block diagram of a receiver of a MIMO FBMC system according to an embodiment of the present invention.
6 is a flowchart showing an overall flow of an interference cancellation method in a receiving apparatus of an FBMC system according to an embodiment of the present invention.
7 is a diagram illustrating a reference symbol allocation structure in an FBMC system according to an embodiment of the present invention.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

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

1 is a diagram illustrating an example of arranging reference symbols of multiple antennas in a general OFDM system.

In a communication system using OFDM, channel estimation is performed using a reference symbol (RS). The reference symbol is a symbol previously known between the transmitting end and the receiving end, and estimates the channel through how the reference symbol has changed via the channel. That is, the reference symbol is a symbol used in a wireless mobile communication system to measure the state of a channel between a receiver and a receiver through a channel strength, a distortion, an interference strength, a Gaussian noise, .

In the case of a wireless mobile communication system using a multi-carrier, a difference occurs in channel estimation performance depending on how many time symbols and sub-carrier intervals are arranged in time and frequency. Generally, as the number of reference symbols increases with time and subcarriers, the channel estimation performance improves, thereby improving the demodulation and decoding performance of symbols of received data. However, there is a disadvantage in that the number of data symbols that can be arranged by the number of the reference symbols is reduced, and the amount of data to be transmitted is reduced.

Such a reference symbol is inserted and transmitted at predetermined positions between data symbols while transmitting data symbols, and FIG. 1 shows an example of arranging reference symbols in a general MIMO OFDM communication system.

FIG. 1 shows an example of arranging reference symbols when two antennas (antenna 0 and antenna 1) are used, red and blue are regions in which reference symbols are arranged in each antenna, white is an area in which data is arranged, Is an area in which no data is arranged.

In the resource element map shown in FIG. 1, the x-axis means time and the y-axis means frequency.

Referring to FIG. 1, in a communication system using OFDM, two antennas place reference symbols at different coordinates. In addition, other antennas do not place any data in the coordinates on which the reference symbols of the particular antenna are arranged.

It can be seen from FIG. 1 that reference symbols are arranged at the (5, 3) coordinates of the resource element map in antenna 0, and no data is arranged in the corresponding coordinates in antenna 1.

On the other hand, it can be seen from FIG. 1 that the reference symbol is arranged at the (1,3) coordinate of the resource element map in the antenna 1, but no data is arranged in the corresponding coordinate of the antenna 0.

From the viewpoint of the receiver, since only the reference symbol of the antenna 0 is received at the (5, 3) coordinates, the channel estimation for the antenna 0 becomes possible using the reference symbol. Also, since only the reference symbol of the antenna 1 is received at the (1, 3) coordinate, the channel estimation for the antenna 1 becomes possible using the reference symbol.

In a communication system using OFDM, orthogonality is guaranteed for each resource element, so that it is possible to perform a relatively accurate channel estimation using a reference symbol when no data is included in another antenna at a position where the reference symbol of the specific antenna is placed.

In an FBMC communication system using a filter bank, interference occurs between resource elements, so that each antenna arranges a reference symbol in different resource elements and a configuration in which no other antenna places data in a resource element in which a reference symbol of a specific antenna is arranged It is difficult to accurately estimate the channel.

2 is a view for explaining interference that occurs when the MIMO FBMC is used.

Referring to FIG. 2, in a communication system using a MIMO FBMC, data of each resource element affects data of other resource elements. Due to this characteristic, data stored in each resource element is interfered by neighboring data do.

The reference symbol 200 of a particular resource element of antenna 1 is affected by data contained in other resource elements of the main surface. The reference symbol 200 is affected not only by the data of the other resource element of the antenna 1 but also by the antenna 0.

No data or reference symbol is allocated to the coordinates of the antenna 0 corresponding to the coordinates in which the corresponding reference symbol 200 is arranged in the antenna 1. However, since the surrounding data of the coordinates are influenced, the interference occurs.

FIG. 3 is a diagram for more specifically explaining the interference that occurs when the FBMC is used.

Referring to FIG. 3, the reference symbol 200 of antenna 1 is interfered with from other coordinate resource elements. In FIG. 3, interference received from data symbols of different coordinates is indicated by a blue line, and interference received from reference symbols of other coordinates is indicated by a black line.

3, interference is also provided at the coordinates corresponding to the reference symbol 200 at the antenna 0, and this interference is caused by the surrounding data symbols and the reference symbols of the corresponding coordinates.

The interference provided from the data symbol during the interference provided at the corresponding coordinates in antenna 0 is indicated by a red line, and the interference provided from the reference symbol is indicated by a black line.

In other words, the reference symbol of the specific coordinates of the antenna 1 not only interferes due to influence from the neighboring data symbol or the reference symbol but also influences from the surrounding data symbol or reference symbol of the coordinate corresponding to the corresponding coordinate of the antenna 0, .

As a result, the interference provided to the reference symbol of a specific coordinate of a specific antenna can be expressed as a sum of the interference provided from the surrounding data of the antenna and the interference provided from the surrounding data of the corresponding coordinates of the other antenna.

If the conventional channel estimation method of a communication system using OFDM is used as it is due to such interference, a considerable channel estimation error is inevitable. However, a proper channel estimation method in the FBMC communication system is insufficient.

The interference from the surrounding data provided to the resource element of the specific coordinate is predictable based on the filter coefficient of the FBMC system to be used. That is, since the impulse response is preset for each of the time and frequency (subcarriers) for the filter used in the FBMC, the interference from the surrounding data can be predicted.

4 is a diagram showing an example of an impulse response for each time and frequency of the FBMC filter.

Referring to FIG. 4, an impulse response of a neighboring resource element is displayed based on a center time and frequency, and it is possible to predict interference based on the impulse response.

However, even if the impulse response for each filter is known as shown in FIG. 4, it is necessary to know the data stored in the surrounding resource elements to calculate accurate interference. The accurate data stored in each resource element can be known only after the decoding is completed.

Accordingly, the present invention proposes a method of estimating a channel by predicting and canceling the interference generated from the known reference symbol, which is already known.

The channel estimation method of the present invention to be described below estimates a channel through iterative computation and predicts and removes interference generated from a reference symbol already known in removing an interference component in a repetitive calculation.

Hereinafter, a configuration of a receiving apparatus of a MIMO FBMC system for more accurately estimating a channel using an impulse response of a filter and surrounding reference symbols will be described in detail.

5 is a block diagram of a receiving apparatus of a MIMO FBMC system according to an embodiment of the present invention.

5, the channel estimation apparatus of the FBMC system according to an embodiment of the present invention includes an RS extractor 500 for each antenna, a first channel coefficient estimator 502 for each antenna, a second channel coefficient estimator 502 for each antenna, A total interference amount calculation unit 504 and an antenna-specific total interference amount calculation unit 506 and a channel coefficient update unit 508.

The signal s [k] transmitted by the transmitting apparatus in the MIMO FBMC system can be expressed by the following equation (1).

는 QAM 변조된 송신 심볼,

는 송신단의 FBMC 필터 응답으로서 M은 부반송파의 개수를 의미하고 L은 FBMC 필터의 길이를 의미한다. In Equation (1), i is an antenna index, m is a frequency index, n is a time index,

QAM modulated transmit symbols,

Is the FBMC filter response of the transmitter, M is the number of subcarriers, and L is the length of the FBMC filter.

In the MIMO FBMC system, the received signal at the time index k can be expressed by the following equation (2).

시간 인덱스 k에서의 채널 정보이다. In Equation (2), E _s is an average transmission power, N _T is a number of transmitting end antennas,

And channel information at time index k.

In FIG. 5, the RS extractor 500 for each antenna extracts a reference symbol received from each antenna. In the example shown in FIG. 3, a reference symbol for antenna 0 and a reference symbol for antenna 1 are independently extracted.

The received reference symbol extracted from each antenna can be expressed by Equation (3).

는 (p,q) 좌표에서 송신된 레퍼런스 심볼에 해당되며

는 p,q 좌표에서의 채널 계수를 의미하고

는 i번째 안테나에서 (p.q) 좌표에서의 간섭량을 의미하며,

는 i번째 안테나에 존재하는 모든 레페런스 심볼들의 좌표 집합을 의미한다.In Equation (3), p and q mean the coordinates of the resource element map,

Corresponds to a reference symbol transmitted at (p, q) coordinates

Denotes a channel coefficient in the p and q coordinates

Denotes the interference amount in the (pq) coordinate at the i-th antenna,

Denotes a coordinate set of all reference symbols existing in the ith antenna.

As can be seen from Equation (3), the reference symbol extracted by the RS extracting unit for each antenna is a signal to which interference is added to the reference symbol transmitted from the transmitting end. As described above, the reference symbol in the specific resource element is interfered with the data of the neighbor resource element, and the value obtained by adding the interference in all the antennas becomes the total interference amount.

The first channel coefficient estimator 502 for each antenna estimates a channel coefficient using a reference symbol extracted by an RS extracting unit for each antenna. Specifically, the channel-dependent channel coefficient estimator 502 estimates a channel coefficient using a reference symbol extracted for each resource element. Since the channel coefficient is estimated using the reference symbol, only the channel coefficient in the resource element in which the reference symbol is allocated is estimated for each antenna.

The estimation of the channel coefficient for each antenna can be performed as Equation (4).

은 미리 알고 있는 각 리소스 엘리먼트 좌표에서의 레퍼런스 심볼값을 의미하고,

은 수학식 3으로부터 p,q 좌표에서 추출되는 수신 심볼값을 의미한다. 즉, 레퍼런스 심볼이 위치한 리로스 엘리먼트 좌표에서 추출한 수신 심볼값을, 미리 알고 있는 레퍼런스 심볼 값으로 나누어 줌으로써 상기 좌표에서의 채널 계수를 추정하게 된다.In Equation (4) above,

Denotes a reference symbol value in each resource element coordinate which is known in advance,

Denotes a received symbol value extracted from the p and q coordinates from Equation (3). That is, the channel coefficient in the above coordinates is estimated by dividing the received symbol value extracted from the reference position of the reference element by the reference symbol value previously known.

The channel coefficient estimation is performed for resource elements in which reference symbols are arranged for each antenna.

The second channel coefficient estimator for each antenna 504 estimates a channel coefficient for a resource element in which the data symbol is located, and performs channel coefficient estimation using interpolation. Since it is a well-known technique to estimate the channel coefficient in the resource element in which the data symbol after the channel estimation in the resource element in which the reference symbol is placed is interpolated, detailed description thereof will be omitted.

For example, the interpolation may be performed using the average of known channel coefficients, the weighted average, and the like.

When the interpolation in the second channel coefficient estimating unit 504 for each antenna is completed, the channel coefficient in each resource element is primarily estimated. However, this is not an accurately estimated channel coefficient since it is an estimate of the channel coefficient that does not exclude interference.

After the channel is primarily estimated, the total interference amount calculation unit 506 for each antenna calculates the total interference amount for each antenna. As described above, the interference from the resource element placed in the data symbol can not be estimated, and the present invention estimates the interference amount from the resource element in which the neighboring reference symbol capable of predicting the interference amount is disposed, and calculates the total interference amount.

를 추정한다. 여기서 시간 인덱스는 리소스 엘리먼트에서 특정 시간축에서의 전체 채널 정보를 의미한다. In order to estimate the interference amount from the resource element in which the neighboring reference symbol is placed, the channel information at the specific time index k

. Here, the time index refers to full channel information at a specific time axis in a resource element.

The channel information at the specific time index k can be estimated as Equation (5).

The total interference amount calculation unit for each antenna calculates the total interference amount in the specific resource element coordinates for each antenna using the channel information at the specific time index. The calculation of the interference amount can be calculated by the following Equation (6).

는 레퍼런스 심볼이 실린 위치 정보를 위미하고,

는 해당 위치에서의 레퍼런스 심볼 값을 의미하며,

는 시간 인덱스 k에서의 채널 정보를 의미하며, g[k]는 FBMC에서 사용하는 필터 응답을 의미한다. In Equation (6), m and n are frequency and time indexes of a transmission signal, i is an antenna index, N _T is the total number of antennas, p and q are resource element coordinates,

Lt; RTI ID = 0.0 > symbol < / RTI >

Denotes a reference symbol value at the corresponding position,

Denotes channel information at the time index k, and g [k] denotes a filter response used in the FBMC.

Equation (6) is a value obtained by adding the interference from the resource element in which all surrounding reference symbols are arranged for each antenna, and the interference from each resource element can be estimated using the impulse response of the filter used in the FBMC.

The channel coefficient update unit 508 updates the channel coefficient information by removing the total interference amount calculated from the estimated channel coefficient. The channel coefficient update unit 508 updates the channel coefficient by subtracting the interference amount calculated by the antenna-based total interference amount calculation unit 506 from the channel coefficient that is primarily estimated.

The update of the channel coefficient can be expressed by the following Equation (7).

Such updating of channel coefficients is repeatedly performed, and the number of repetitions may be set in various ways. For example, repeated channel coefficient updates may be performed until the difference between the previous channel coefficient and the current channel coefficient converges to a predetermined value or less. Alternatively, the number of repetitions may be preset and the channel update may be performed up to the number of repetitions.

6 is a flowchart illustrating an overall flow of an interference cancellation method in a receiving apparatus of an FBMC system according to an embodiment of the present invention.

Referring to FIG. 6, a reference symbol is extracted for each antenna from a received signal (step 600). The extracted reference symbol is a reference symbol including interference, and firstly, reference symbols in a state including interference are extracted for each antenna.

When the reference symbols are extracted for each antenna, a channel coefficient is estimated for each antenna (step 602). The channel coefficient for each antenna is estimated using a known reference symbol value, and a channel coefficient is estimated for each coordinate of the resource element in which the reference symbol is arranged.

If the channel coefficient estimation is performed, channel coefficients of coordinates at which the data symbols are arranged using the estimated channel coefficients for the reference symbols are estimated through interpolation (step 604).

When the channel coefficient is primarily estimated through the interpolation, the total interference amount is calculated using the neighboring reference symbols (step 606). The total interference amount can be calculated as shown in Equation (7).

When the total interference amount is calculated, the channel coefficient is updated by subtracting it from the channel coefficient primarily estimated (step 608).

The update of the channel coefficient is repeated until a predetermined condition is satisfied (step 610). As described above, the repetition condition may be variously set.

When the estimation of the channel coefficient is completed, equalization is performed (step 612).

7 is a diagram illustrating a reference symbol allocation structure in an FBMC system according to an embodiment of the present invention.

Referring to FIG. 7, in the FBMC system, it is preferable that the reference symbol be placed on the resource elements adjacent in time to the parts having the greatest interference amount based on the impulse response of the FBMC filter.

It can be seen from Fig. 7 that the four antennas are arranged adjacent to each other on the time axis, and the reference symbols are arranged. The reason for arranging the reference symbols adjacent to the parts with large interference amounts is because the channel estimation method of the present invention removes the interference using the reference symbols and the interference cancellation effect is larger than that when the reference symbols are arranged in a place with a large interference amount. It is because it can plan.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

Claims (16)

A reference symbol extracting unit for extracting a reference symbol for each antenna;
A first channel coefficient estimator for estimating a channel coefficient of resource elements in which reference symbols are arranged using the extracted reference symbol information;
A second channel coefficient estimator for estimating a channel coefficient of resource elements in which data symbols are arranged using channel coefficients of resource elements in which the reference symbols estimated by the first channel coefficient estimator are arranged;
A total interference amount calculating unit for calculating an interference amount by neighboring reference symbols for each antenna using an impulse response of the FBMC filter to calculate a total interference amount; And
And a channel coefficient updating unit for updating the channel coefficient by subtracting the total interference amount calculated by the total interference amount calculation unit from the channel coefficients estimated by the second channel coefficient estimation unit using interpolation,
Wherein the channel coefficient updating unit repeats channel coefficient updating based on a preset condition. ≪ RTI ID = 0.0 > 8. < / RTI > The method according to claim 1,
Wherein the total interference amount calculation unit sums the interference amount due to neighboring reference symbols for each resource element coordinate using the impulse response of the FBMC filter. 3. The method of claim 2,
Wherein the total interference amount calculation unit estimates channel information in a specific time axis of the resource element map, and then calculates a total interference amount using the estimated channel interference information. The method of claim 3,
Wherein the total interference amount calculating unit calculates a total interference amount according to the following equation: < EMI ID = 1.0 >

Where m and n are the frequency and time index of the transmission signal, i is the antenna index, N _T is the total number of antennas, p and q are the resource element coordinates,

The position information containing the reference symbol is favored,

Denotes a reference symbol value at the corresponding position,

Denotes channel information at a specific time axis k, and g [k] denotes a filter response used in the FBMC. The method according to claim 1,
Wherein the channel update unit updates the channel according to the following equation.

In the above equation,

Denotes an updated channel coefficient in the resource element p and q coordinates

Denotes a channel coefficient in the p and q coordinates of the resource element before the update,

Is the total amount of interference in the p and q coordinates of the resource element. 5. The method of claim 4,
Wherein channel information on a specific time axis of the resource element map is estimated according to the following equation.

The method according to claim 1,
Wherein the updating of the channel coefficient is repeated until a difference between a previous channel coefficient and a current channel coefficient becomes equal to or less than a preset threshold value. The method according to claim 1,
Wherein the updating of the channel coefficient is performed until a preset number of repetitions is reached. The method according to claim 1,
Wherein the second channel coefficient estimator estimates channel coefficients of resource elements in which the data symbols are arranged using interpolation. (A) extracting a reference symbol for each antenna;
(B) estimating channel coefficients of resource elements in which reference symbols are arranged using the extracted reference symbol information;
(C) estimating channel coefficients of resource elements in which data symbols are arranged using channel coefficients of resource elements in which the reference symbols estimated by the step (b) are arranged;
(D) calculating an interference amount by neighboring reference symbols for each antenna using an impulse response of the FBMC filter to calculate a total interference amount; And
(E) updating channel coefficients by subtracting the total interference amount calculated in step (d) from channel coefficients estimated in step (c) using interpolation,
Wherein the channel coefficient update in the step (e) is repeated based on a preset condition. 11. The method of claim 10,
Wherein the step (d) sums the amount of interference due to the neighboring reference symbols by the resource element coordinates using the impulse response of the FBMC filter. 12. The method of claim 11,
Wherein the step (d) estimates channel information on a specific time axis of the resource element map and then calculates a total interference amount using the estimated channel information. 13. The method of claim 12,
Wherein the step (d) computes a total interference amount as follows: < EMI ID = 1.0 >

Where m and n are the frequency and time index of the transmission signal, i is the antenna index, N _T is the total number of antennas, p and q are the resource element coordinates,

The position information containing the reference symbol is favored,

Denotes a reference symbol value at the corresponding position,

Denotes channel information at a specific time axis k, and g [k] denotes a filter response used in the FBMC. 12. The method of claim 11,
Wherein the step (e) is performed according to the following equation.

In the above equation,

Denotes an updated channel coefficient in the resource element p and q coordinates

Denotes a channel coefficient in the p and q coordinates of the resource element before the update,

Is the total amount of interference in the p and q coordinates of the resource element. 14. The method of claim 13,
Wherein the channel information at a specific time axis of the resource element map is estimated according to the following equation.

11. The method of claim 10,
Wherein the step (c) estimates channel coefficients of resource elements in which data symbols are arranged using interpolation.

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