KR100963334B1 - Pilot placement method and recording medium - Google Patents

Abstract

A wireless signal transmission apparatus for transmitting an uplink frame including a tile receives pilot position information from a base station, and includes a plurality of adjacent adjacent first sides of the tile and spaced apart from the second side of the tile at predetermined intervals according to the pilot position information. Place the first pilot of the first layer at one of the symbol positions. In addition, the apparatus for transmitting a wireless signal arranges the second pilot of the first layer at one of a plurality of symbol positions adjacent to the third side of the tile and spaced apart from the second side of the tile at predetermined intervals according to the pilot position information. Placing a third pilot of the first layer at one of a plurality of symbol positions adjacent to the first side and spaced at predetermined intervals from the fourth side of the tile, adjacent to the third side of the tile and predetermined from the fourth side of the tile. The fourth pilot of the first layer is disposed at one of the plurality of symbol positions spaced apart.

OFDMA, pilot, batch, tile

Description

Pilot design method and recording medium

The present invention relates to a pilot arrangement method and a recording medium. In particular, the present invention relates to a pilot placement method for multiple layers in an uplink frame of an orthogonal frequency division multiplex (OFDMA) system.

Orthogonal Frequency Division Multiplexing (OFDM) scheme is a communication scheme in which high-speed serial data is separated into a low-speed parallel signal and modulated by sub-carriers orthogonal to each other. .

Orthogonal Frequency Division Multiplex Access (OFDMA), also known as OFDMA, or OFDM-FDMA, is one of multiple access schemes. A plurality of two-dimensional maps in which radio resources of a limited uplink / downlink are divided into time and frequency axes are divided. Allocate a portion of resources to each layer of, and place only one layer for that portion of resources. In this case, the layer may be represented as a product of the number of users and the number of transmitting antennas when the plurality of users each use the plurality of transmitting antennas.

Meanwhile, in order to compensate for the distortion of the symbol size and phase due to the multipath attenuation caused by the radio channel, channel estimation using a pilot may be used. Here, the pilot means a signal of a structure or form promised by the transmitting end and the receiving end. Such a pilot is allocated to some subcarriers of a tile, which is a basic unit of radio resource allocation, and a receiving end can estimate a channel value of a corresponding channel using a pilot.

According to the method of arranging the pilots corresponding to the multi-layers in the uplink frame, the pilot overhead of the uplink frame is determined, and the method of determining the pilot of each of the multi-layers is determined. Since the transmission efficiency of the link frame and the accuracy of channel estimation are different, an efficient pilot placement method is needed.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a pilot arrangement method and a recording medium capable of reducing pilot overhead and improving accuracy of channel estimation.

According to a feature of the present invention for solving the above problems, a method for arranging a pilot for one of a plurality of layers in an uplink frame including a tile comprises the steps of: receiving pilot position information from a base station; Arranging a first pilot corresponding to the one layer at one of a plurality of first symbol positions adjacent to the first side of the tile and spaced apart from the second side of the tile by a predetermined interval according to the pilot position information; ; Arranging a second pilot corresponding to the one layer at one of a plurality of second symbol positions adjacent to a third side of the tile and spaced apart from the second side of the tile at predetermined intervals according to the pilot position information; step; Disposing a third pilot corresponding to the one layer at one of a plurality of third symbol positions adjacent to the first side of the tile and spaced apart from the fourth side of the tile by the predetermined interval according to the pilot position information; And a fourth pilot corresponding to the one layer at one of a plurality of fourth symbol positions adjacent to the third side of the tile and spaced apart from the fourth side of the tile at predetermined intervals according to the pilot position information. Deploying.

The disposing of the first pilot may include disposing a data symbol at at least one symbol position among the plurality of first symbol positions, and disposing the second pilot may include disposing the second pilot position. Disposing a data symbol at at least one symbol position, and disposing the third pilot includes disposing a data symbol at at least one symbol position among the plurality of third symbol positions, The disposing of the fourth pilot includes disposing a data symbol at at least one symbol position among the plurality of fourth symbol positions. The disposing of the first pilot may include disposing the first pilot at a symbol position located at a minimum distance from a first vertex which is an intersection point of the first side and the second side among the plurality of first symbol positions. The method may further include disposing the second pilot at the symbol position located at a minimum distance from a second vertex which is an intersection point of the first side and the fourth side among the plurality of second symbol positions. The method may further include disposing a pilot, wherein disposing the third pilot may further include disposing the third pilot at a symbol position located at a minimum distance from the first vertex of the plurality of third symbol positions. The disposing of the fourth pilot may include disposing the fourth pilot at a symbol position located at a minimum distance from the second vertex of the plurality of fourth symbol positions. Further it includes a system.

The disposing of the first pilot may include disposing the first pilot at a symbol position located at a minimum distance from a first vertex that is an intersection point of the first side and the second side among the plurality of first symbol positions. Wherein the placing of the second pilot includes placing the second pilot at a symbol position located at a minimum distance from the first vertex of the plurality of second symbol positions, wherein the third pilot is disposed. The disposing of the pilot may include disposing the third pilot at a symbol position located at a minimum distance from the first vertex of the plurality of third symbol positions, and disposing the fourth pilot may include the plurality of third pilot positions. And arranging the fourth pilot at a symbol position located at a minimum distance from the first vertex of the fourth symbol positions of.

And arranging the first pilot further includes arranging a null symbol at the remaining one of the plurality of first symbol positions, and arranging the second pilot at the remaining one of the plurality of second symbol positions. The method may further include disposing a null symbol, wherein disposing the third pilot may further include disposing a null symbol at the remaining one of the plurality of third symbol positions, and disposing the fourth pilot. Disposing a null symbol at a remaining one of the plurality of fourth symbol positions. In addition, the tile is divided into 10 subcarriers on the frequency axis and 6 symbol intervals on the time axis.

According to another feature of the present invention, in a recording medium storing an uplink frame, the uplink frame includes at least one tile, and the tile is located at a first vertex of the tile according to pilot position information of the base station. A first pilot disposed at one of a plurality of adjacent first symbol positions, a second pilot disposed at one of a plurality of second symbol positions adjacent to a second vertex of the tile according to pilot position information of the base station; A third pilot disposed at one of a plurality of third symbol positions adjacent to the third vertex of the tile according to the pilot position information of the base station, and a plurality of adjacent to the fourth vertex of the tile according to the pilot position information of the base station And a fourth pilot disposed at one of the fourth symbol positions. Here, the plurality of first symbol positions and the plurality of second symbol positions are spaced apart from the first side of the tile by a predetermined interval, and the plurality of third symbol positions and the plurality of fourth symbol positions are the first It is spaced apart from the second side of the tile facing the side at the predetermined interval.

The first pilot is disposed at a symbol position positioned at a minimum distance from the first vertex among the plurality of first symbol positions, and the second pilot is disposed at a minimum distance from the third vertex among the plurality of second symbol positions. Wherein the third pilot is disposed at a symbol position positioned at a minimum distance from the first vertex among the plurality of third symbol positions, and the fourth pilot is selected from the plurality of fourth symbol positions. The symbol is positioned at a symbol located at a minimum distance from the third vertex. In this case, the tile may include data symbols disposed at at least one symbol position in each of the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions. It includes more.

The first pilot is disposed at a symbol position positioned at a minimum distance from the first vertex among the plurality of first symbol positions, and the second pilot is disposed at a minimum distance from the first vertex among the plurality of second symbol positions. The third pilot is disposed at a symbol position located, wherein the third pilot is disposed at a symbol position located at a minimum distance from the first vertex among the plurality of third symbol positions, and the fourth pilot is selected from among the plurality of fourth symbol positions. The symbol is positioned at a symbol located at a minimum distance from the first vertex.

The tile further includes a null symbol disposed at a remaining symbol position in each of the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions. The tile is divided into a plurality of subcarriers in a frequency domain and is divided into a plurality of symbol intervals in a time domain, and the predetermined interval is the at least one subcarrier.

According to still another aspect of the present invention, in a recording medium storing an uplink frame, the uplink frame includes a tile, the plurality of uplink frames adjacent to the first side of the tile and spaced apart from the second side by a predetermined interval. A pilot of a first layer and a pilot of a second layer are respectively disposed at a first symbol position, and the first at a plurality of second symbol positions adjacent to a third side of the tile and spaced apart from the second side by a predetermined interval. A pilot of the layer and a pilot of the second layer are respectively disposed, and the pilot and the second layer are located at a plurality of third symbol positions adjacent to the first side of the tile and spaced apart from the fourth side by a predetermined interval. Pilots of the hierarchy are each disposed, and are located in a plurality of fourth symbol positions adjacent to the third side of the tile and spaced apart from the fourth side by a predetermined interval. A pilot and a pilot of the second layer are respectively disposed.

The pilot of the first hierarchical symbol is located at a minimum distance from a first vertex that is an intersection point of the first side and the second side at each of the plurality of first symbol positions and the plurality of third symbol positions; Disposed at a symbol position located at a minimum distance from a second vertex that is an intersection point of the first side and the fourth side at each of the plurality of second symbol positions and the plurality of fourth symbol positions, and the pilot of the second layer is A symbol position located at a minimum distance from a third vertex which is an intersection point of the second side and the third side at each of the plurality of first symbol positions and the plurality of third symbol positions, and the plurality of second symbol positions and the Each of the fourth symbol positions is disposed at a symbol position located at a minimum distance from a fourth vertex that is an intersection point of the third side and the fourth side. In this case, a data symbol is further disposed at at least one symbol position in each of the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions.

And a pilot of a third layer and a pilot of a fourth layer are respectively disposed at the plurality of first symbol positions, and a pilot of the third layer and a pilot of the fourth layer are respectively disposed at the plurality of second symbol positions. And the pilot of the third layer and the pilot of the fourth layer are respectively disposed at the plurality of third symbol positions, and the pilot of the third layer and the pilot of the fourth layer are respectively located at the plurality of fourth symbol positions. Is placed. In this case, the pilot of the first layer may include the first side and the second side at each of the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions. Disposed at a symbol position located at a minimum distance from a first vertex that is an intersection point of the second hierarchy, and the pilot of the second layer includes the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the Each of the plurality of fourth symbol positions is disposed at a symbol position located at a minimum distance from a second vertex, which is an intersection point of the second side and the third side, and the pilot of the third layer is located in the plurality of first symbol positions. And a shim positioned at a minimum distance from a third vertex that is an intersection point of the first side and the fourth side at each of the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions. And a pilot of the fourth layer includes the third side at each of the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions. And a fourth vertex, which is an intersection point between the fourth side and the fourth side, at a symbol position located at a minimum distance.

In addition, the tile is divided into 10 subcarriers in the frequency domain, and is divided into six symbol intervals in the time domain.

According to the present invention, since each pilot is orthogonally arranged using null symbols, overall channel estimation may be performed by applying a linear interpolation scheme, thereby improving accuracy of channel estimation. In addition, it is possible to reduce pilot overhead in the uplink frame.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise. In addition, the terms “… unit”, “… unit”, “module”, etc. described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. have.

In this specification, a mobile station (MS) includes a terminal, a mobile terminal (MT), a subscriber station (SS), a portable subscriber station (PSS), and a user equipment. It may also refer to a user equipment (UE), an access terminal (AT), and the like, and may include all or some functions of a mobile terminal, a subscriber station, a portable subscriber station, a user device, and the like.

In the present specification, a base station (BS) is an access point (AP), a radio access station (Radio Access Station, RAS), a Node B (Node B), a base transceiver station (Base Transceiver Station, BTS), MMR ( Mobile Multihop Relay) -BS and the like, and may include all or part of functions such as an access point, a radio access station, a Node B, a base transceiver station, and an MMR-BS.

Hereinafter, a pilot arrangement method and a recording medium according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a wireless signal transmission apparatus according to an embodiment of the present invention, Figure 2 is a flow chart of a wireless signal transmission method according to an embodiment of the present invention.

As shown in FIG. 1, the apparatus for transmitting a wireless signal includes an encoder 110, a digital modulator 120, a subchannel allocator 130, and an inverse fast fourier transform (IFFT). IFFT ", 140), a Cyclic Prefix (CP) inserter 150 (shown as" CP inserter "in FIG. 1) and a transmitter 160. In FIG. 1, only some of OFDMA transmitting apparatuses related to transmitting an uplink frame corresponding to any one layer are illustrated.

As shown in FIG. 2, the encoder 110 encodes data at a corresponding code rate (S210).

The digital modulator 120 digitally modulates the encoded data (S220).

The subchannel allocator 130 determines a subchannel for transmitting digitally modulated data. The subchannel includes a plurality of tiles that are continuous or non-contiguous, each tile including a plurality of subcarriers in the frequency domain, and a plurality of symbol intervals in the time domain. The subchannel allocator 130 allocates a symbol position of a tile to each data (S230). In this case, the symbol position means a radio resource where one subcarrier and one symbol position intersect in a tile.

The subchannel allocator 130 allocates the symbol positions of the tiles to the pilot of the corresponding layer according to the pilot position information of the corresponding layer received from the base station (S240). Here, the pilot is a signal of a structure or type promised by the base station and the radio signal transmission apparatus, and is used for channel estimation to compensate for the distortion of the magnitude and phase of the signal by the radio channel.

The inverse Fourier transform unit (IFFT) 140 converts the data and the pilot from the signal in the frequency domain to the signal in the time domain according to the corresponding subcarriers to generate a signal using a plurality of symbols (S250).

The guard interval insertion unit 150 inserts a guard interval of a time domain for maintaining orthogonality between subcarriers between a plurality of symbols (S260).

The transmitter 160 transmits a radio signal of an uplink frame including a plurality of symbols in which a guard interval is inserted into the uplink through an antenna (S270).

On the other hand, the uplink for transmitting a signal from the radio signal transmission apparatus to the base station is divided into a plurality of subchannels respectively corresponding to multiple layers. Here, the multi-layer means a product of the number of the plurality of users and the number of transmit antennas corresponding to each user.

In particular, since the base station should be able to recognize which layer the pilot of the radio signal received through the uplink corresponds to, according to an embodiment of the present invention, the apparatus for transmitting a radio signal is different depending on the layer corresponding to the layer Is placed on the tile.

3 is a diagram showing a pilot arrangement according to the first embodiment of the present invention.

As shown in FIG. 3, according to the first embodiment, a tile is divided into four subcarriers in the frequency domain and divided into three symbol intervals in the time domain, thereby having a 4x3 structure. In such a 4x3 tile, a pilot or null symbol is placed at symbol location L1 and symbol location L2 adjacent to each of the four vertices.

That is, according to the first embodiment, the wireless signal transmission apparatus for transmitting the signal of the first layer of the second layer, according to the pilot position information received from the base station, arranges the pilot at the symbol position (L1) of the 4x3 structure tile and null Place the symbol at symbol position L2. The wireless signal transmission apparatus transmitting the signal of the second layer of the second layer according to the pilot position information received from the base station, arranges the pilot at the symbol position (L2) of the 4x3 structure tile and the null symbol at the symbol position (L1) To place. As described above, according to the first embodiment, the pilots of each of the second layers are orthogonally arranged using null symbols on tiles of a 4x3 structure, and the base station performs channel estimation using four pilots included in the 4x3 structure tile.

Therefore, according to the pilot arrangement method of the first embodiment, the pilot overhead (overhead = (symbol position where the pilot or null symbol is placed / total symbol position)) is 33.3% from 4/12.

Meanwhile, according to the first embodiment, in order to distinguish the pilots corresponding to each of the four layers, the pilots of the two layers are orthogonally arranged using a null symbol, and the pilots of the remaining two layers are overlapped orthogonally arranged. Hereinafter, a pilot arrangement method of four layers according to the first embodiment will be described.

The wireless signal transmission device for transmitting the signal of the first layer and the wireless signal transmission device for transmitting the signal of the second layer among the four layers include the pilot at the symbol position L1 of the 4x3 structure tile according to the pilot position information received from the base station. And null symbol at symbol position L2. The wireless signal device transmitting the signal of the third layer and the wireless signal transmitting device transmitting the signal of the fourth layer among the four layers may transmit the pilot to the symbol position L2 of the 4x3 structure tile according to the pilot position information received from the base station. And null symbol at symbol position L1. In this case, the apparatus for transmitting a signal of the second layer transmits pilots having opposite codes to symbol positions L1 to distinguish them from pilots of the first layer. Similarly, the apparatus for transmitting a signal of the fourth layer transmits pilots having opposite codes to symbol positions L2 to distinguish them from the pilot of the third layer.

Accordingly, the base station recognizes that the pilot disposed at the symbol location L1 corresponds to the first layer or the second layer, and the pilot located at the symbol location L2 is recognized as the third layer or the fourth layer. do. Further, the base station determines that the pilot obtained from the sum of the symbol positions L1 corresponds to the first layer, and the pilot obtained from the difference value of the symbol positions L1 corresponds to the second layer. Similarly, the base station determines that the pilot obtained from the sum of the symbol positions L2 corresponds to the third layer, and the pilot obtained from the difference value of the symbol positions L2 corresponds to the fourth layer.

As described above, according to the pilot arrangement method of the fourth layer according to the first embodiment, since the pilot or null symbols are arranged at four symbol positions in the 4x3 structure tile, the pilot overhead is 33.3% which is the same as the pilot arrangement method of the second layer. to be.

4 is a diagram showing a pilot arrangement according to a second embodiment of the present invention.

As shown in FIG. 4, according to the second embodiment, a tile is divided into 10 subcarriers in the frequency domain and divided into 6 symbol intervals in the time domain to have a 10 × 6 structure. In such a 10x6 tile, a pilot or null symbol is disposed in the symbol section L1 and the symbol section L2. In this case, the symbol period L1 and the symbol period L2 are radio resources where each of the first subcarrier, the fifth subcarrier, and the ninth subcarrier and the first symbol period, the second symbol period, the fifth symbol period, and the sixth symbol period each intersect. .

That is, according to the second embodiment, the wireless signal transmission apparatus for transmitting the signal of the first layer of the second layer is arranged in the symbol position L1 of the 10x6 structure tile according to the pilot position information received from the base station and null symbol Is placed at the symbol position L2. In addition, the apparatus for transmitting a signal of the second layer of the second layer arranges the pilot at the symbol position L2 of the 10x6 structure tile and the null symbol at the symbol position L1 according to the pilot position information received from the base station. do. As described above, according to the second embodiment, the pilots of each of the second layers are orthogonally arranged using null subcarriers in the 10x6 structure tile, and the base station performs channel estimation using 12 pilots included in the 10x6 structure tile.

Therefore, according to the pilot arrangement method according to the second embodiment, the pilot overhead is 20% from 12/60.

5 is a diagram showing a pilot arrangement according to a third embodiment of the present invention.

As shown in FIG. 5, according to the third embodiment, a tile is divided into 16 subcarriers in the frequency domain and divided into 8 symbol intervals in the time domain to have a 16x8 structure. In the 16x8 tile, the pilot is disposed in the symbol section L. FIG. Here, the symbol interval L is the first subcarrier, the fourth subcarrier, the seventh subcarrier, the tenth subcarrier, the thirteenth subcarrier, and the sixteenth subcarrier, respectively, and the first symbol interval, the second symbol interval, the seventh symbol interval, and the eighth subcarrier from the left. The radio resources cross each symbol section.

According to the third embodiment, the wireless signal transmission apparatus for transmitting the signal of the first layer of the second layer arranges the pilot at the symbol position L of the 16x8 structure tile. In addition, the wireless signal transmission apparatus that transmits the signal of the second layer of the second layer also arranges the pilot at the symbol position L of the 16x8 structure tile. In other words, the pilot of the first layer and the pilot of the second layer are orthogonally arranged by overlapping the symbol position L of the 16x8 structure tile. In addition, the pilot value of the pilot of the first layer and the pilot of the second layer is set to be orthogonal to each other, so that the base station distinguishes the layers of the pilot arranged at the symbol position (L).

As described above, according to the third embodiment, since the pilot is placed at 24 symbol positions in the 16x8 structure tile, the pilot overhead is 18.75% from 24/128.

On the other hand, while the second and third embodiments of the present invention have an advantage of lower pilot overhead than the first embodiment, it is difficult to provide a four-layer pilot arrangement method.

Hereinafter, a pilot arrangement method capable of pilot arrangement of not only two layers but also four layers while reducing pilot overhead will be described.

6 is a diagram showing a pilot arrangement according to a fourth embodiment of the present invention.

As shown in FIG. 6, the tile is divided into 10 subcarriers in the frequency domain and divided into 6 symbol intervals in the time domain, thereby having a structure of 10 × 6. In such a 10x6 structure tile, a pilot or null symbol is disposed at symbol positions corresponding to A area, B area, C area, and D area.

Here, the region A includes a plurality of symbol positions where each of the second subcarrier and the third subcarrier intersects with each other and the first symbol interval and the second symbol interval intersect with respect to the left side. The B region includes a plurality of symbol positions where each of the second subcarrier and the third subcarrier intersects with each of the fifth symbol interval and the sixth symbol interval. The C region includes a plurality of symbol positions where each of the eighth subcarrier and the ninth subcarrier intersects with each of the first symbol period and the second symbol period. The D region includes a plurality of symbol positions where each of the eighth subcarrier and the ninth subcarrier intersects with the fifth symbol interval and the sixth symbol interval.

That is, areas A and B are spaced apart by a predetermined distance corresponding to the first subcarrier from the upper first side in the 10x6 structure tile, and areas C and D are positioned at the last subcarrier from the lower second side in the 10x6 structure tile. It is spaced apart by a predetermined distance. Regions A and C are also located adjacent to the third side on the left side of the 10x6 structure tile, and regions B and D are located adjacent to the fourth side on the right side of the 10x6 structure tile.

First, the pilot arrangement method according to the fourth embodiment when the number of layers using uplink is one will be described first. The radio signal transmission apparatus for transmitting a radio signal through the uplink is a symbol position (L1, L2) of the region A, symbol positions (L3, L4), C of the region B in a 10x6 structure tile according to the pilot position information received from the base station. Pilots are placed at symbol positions L1 and L2 in the region and symbol positions L3 and L4 in the D region. In this way, the pilot overhead is 13.33% from 8/60.

Next, a pilot arrangement method according to the fourth embodiment when the number of layers using uplink is two will be described.

According to the fourth embodiment, two symbol positions of the region A are selected to arrange pilots of each of the two layers in a 10x6 structure tile, and two symbols of the region B which are located on a subcarrier different from the symbol position of the selected region A The location is selected. In addition, two symbol positions of the C region are selected, and two symbol positions of the D region located on a different subcarrier are selected. The pilots of each of the two layers are orthogonally arranged using null symbols at the eight symbol positions thus selected.

For example, a pilot corresponding to each of the two layers uses a null symbol at symbol positions L1 and L2 of regions A and C, and symbol positions L3 and L4 of regions B and D in a 10x6 structure tile. Can be orthogonal. At this time, data is disposed at symbol positions L3 and L4 of the A and C regions, and symbol positions L1 and L2 of the B and D regions, respectively.

That is, the apparatus for transmitting a signal of the first layer of the second layer includes a symbol position L1 and a region B and D of each of the A and C regions in the 10x6 structure tile according to the pilot position information received from the base station. The pilot is placed at the symbol position L3 of, and the null symbol is placed at the symbol position L2 of each of the A and C regions and the symbol position L4 of each of the B and D regions. In addition, the apparatus for transmitting a signal of the second layer of the second layer includes a symbol position (L2) of each of the A region and the C region, and the B region and the D region in the 10x6 structure tile according to the pilot position information received from the base station. The pilot is placed at the symbol position L4, and the null symbol is placed at the symbol position L1 of each of the A and C regions and the symbol position L3 of each of the B and D regions.

Alternatively, the pilots corresponding to each of the two layers may correspond to the symbol positions L3 and L4 of the A and C regions and the symbol positions L1 and L2 of the A and C regions in the 10x6 structure tile. ) Can be orthogonal to the null symbol. At this time, data is disposed at symbol positions L1 and L2 of the A and C regions, and symbol positions L3 and L4 of the B and D regions, respectively.

As described above, according to the fourth embodiment, the pilots of each of the second layers are orthogonally arranged using null symbols in the 10x6 structure tile, and the base station performs channel estimation using eight pilots included in the 10x6 structure tile. Thus, according to the pilot arrangement method of the fourth embodiment for the second layer, the pilot overhead is 13.33% which is the same as the first layer from 8/60.

Next, a pilot arrangement method according to the fourth embodiment for the case where the number of layers using uplink is four will be described.

According to the pilot arrangement method of the fourth embodiment for four layers, the pilots of each of the four layers are orthogonally arranged using null symbols on the 10x6 structure tiles. That is, the pilot corresponding to any one of the four layers is disposed at a symbol position located at a minimum distance from one vertex in each of the A region, the B region, the C region, and the D region.

For example, a wireless signal transmission apparatus for transmitting a signal of a first layer among the four layers may include vertices located in the upper left corners of areas A, B, C, and D according to pilot position information received from a base station. The pilot is placed at the symbol position L1 located at the minimum distance, and the null symbol is placed at the remaining symbol positions L2, L3, L4. The wireless signal transmission apparatus for transmitting signals of the second layer among the four layers is located at a minimum distance from the vertex located at the upper right corner in the A region, the B region, the C region, and the D region according to the pilot position information received from the base station. The pilot is placed at the symbol position L2, and the null symbol is placed at the remaining symbol positions L1, L3, L4. In addition, the wireless signal transmission apparatus transmitting the signal of the third layer among the four layers is located at a minimum distance from the vertex located at the lower left in each of the areas A, B, C and D according to the pilot position information received from the base station. The pilot is placed at the symbol position L3, and the null symbol is placed at the remaining symbol positions L1, L2, and L4. Finally, the wireless signal transmission apparatus transmitting the signal of the fourth layer among the four layers is located at the minimum distance from the vertex located at the lower right corner in the A area, B area, C area, and D area according to the pilot position information received from the base station. The pilot is placed at the symbol position L4 located, and the null symbol is placed at the remaining symbol positions L1, L2, L3.

As described above, according to the fourth embodiment, the pilots of each of the four layers are orthogonally arranged using null symbols in the 10x6 structure tile, and the base station may perform channel estimation using 16 pilots included in the 10x6 structure tile. Since the channel estimation method of the linear interpolation method can be applied, more accurate channel estimation is possible than the pilot arrangement method of the fourth layer according to the first embodiment.

Thus, according to the pilot arrangement method of the fourth embodiment for four layers, the pilot overhead is 26.67% from 16/60.

The following describes the performance of each embodiment of the present invention in comparison.

Table 1 is a table showing the pilot overhead of each of the first, second, third, and fourth embodiments.

As shown in Table 1, in the pilot arrangement method for the second layer, the pilot overhead of the fourth embodiment is 13.33%, so it can be seen that the pilot overhead of the fourth embodiment is the minimum among the embodiments. In addition, when comparing the first embodiment and the fourth embodiment, which is a pilot arrangement method for four layers, the pilot overhead of the fourth embodiment is 26.67%, which is lower than that of the first embodiment, 33.33%.

FIG. 7 is a diagram comparing performance of low SNR measured by applying an average channel estimation method to a pilot layout method of a second layer according to each embodiment of the present invention. FIG. 8 is a diagram illustrating each embodiment of the present invention. Figure 2 compares the performance of the high SNR measured by applying the channel estimation method of the linear interpolation method to the pilot arrangement method of the second layer.

는 제1 실시예에 따른 2계층의 파일롯 배치 방법에 의한 성능을 나타내고,

는 제2 실시예에 따른 2계층의 파일롯 배치 방법에 의한 성능을 나타낸다. 또한,

는 제3 실시예에 따른 2계층의 파일롯 배치 방법에 의한 성능을 나타내며,

는 제4 실시예에 따른 2계층의 파일롯 배치 방법에 의한 성능을 나타낸다.In FIG. 7 and FIG. 8, the solid line means the ITU-R Pedestrian B (speed 3 km / h) channel condition, and the dotted line means the Vehicular A (speed: 60 km / h) channel condition. And in FIGS. 7 and 8,

Denotes the performance by the pilot arrangement method of the second layer according to the first embodiment,

Shows the performance by the pilot arrangement method of the second layer according to the second embodiment. Also,

Shows the performance by the pilot placement method of the second layer according to the third embodiment,

Shows the performance by the pilot arrangement method of the second layer according to the fourth embodiment.

As shown in FIG. 7, when comparing the performance at a low SNR measured by applying the average channel estimation method under ITU-R Pedestrian B (speed 3 km / h) channel condition, the estimated value of the mean square error (FIG. 7 is shown as "MSE of estimation", where MSE means "Mean Squared Error" is 10 ^-1 , the order of the first embodiment, the fourth embodiment, the third embodiment, the second embodiment As shown, high SNR. In the Vehicular A (speed: 60 km / h) channel condition, when the estimated value of the mean square error is 10 ⁻¹ , high SNRs are performed in the order of the first embodiment, the third embodiment, the fourth embodiment, and the second embodiment. Indicates.

As shown in FIG. 8, when the ITU-R Pedestrian B (speed 3 km / h) channel condition is used, the performance of the high SNR measured by applying the channel estimation method of the linear interpolation method is compared. When the estimated value is any value between 10 ^-2 and 10 ^-3 , high SNR is shown in the order of the first embodiment, the fourth embodiment, the second embodiment, and the third embodiment. Further, in the case of the Vehicular A (speed: 60 km / h) channel condition, when the estimated value of the mean square error is any value between 10 ^-2 and 10 ^-3 , the third embodiment, the first embodiment, the fourth embodiment, and the third embodiment High SNR is shown in the order of the two examples.

As described above, when the pilot arrangement method of the second layer according to the fourth embodiment is applied, it can be confirmed that the performance does not significantly decrease as compared with the other embodiments.

FIG. 9 is a diagram comparing performances of low SNR measured by applying an average channel estimation method to a pilot layer layout method according to each of the first and fourth embodiments of the present invention. FIG. The performance of the high SNR measured by applying the channel estimation method of the average method to the pilot placement method of the fourth layer according to the first embodiment of the present invention and the pilot placement method of the fourth layer according to the fourth embodiment of the present invention This is a comparison of the performance at high SNR measured by applying the linear interpolation channel estimation method. In FIG. 10, the pilot arrangement method according to the first embodiment cannot apply the channel estimation method of the linear interpolation method, and thus shows the performance at the high SNR measured by applying the average channel estimation method.

는 제1 실시예에 따른 4계층의 파일롯 배치 방법에 의한 성능을 나타내고,

는 제4 실시예에 따른 4계층의 파일롯 배치 방법에 의한 성능을 나타낸다.In FIG. 9 and FIG. 10, the solid line means the ITU-R Pedestrian B (speed 3 km / h) channel condition, and the dotted line means the Vehicular A (speed: 60 km / h) channel condition. And in FIGS. 9 and 10,

Shows the performance by the four-layer pilot arrangement method according to the first embodiment,

Shows the performance by the pilot layout method of the four layers according to the fourth embodiment.

As shown in FIG. 9, in the ITU-R Pedestrian B (speed 3 km / h) channel condition and the Vehicular A (speed: 60 km / h) channel condition, low SNR measured by applying an average channel estimation method Comparing the performance, it can be seen from the estimated value of any mean square error that the fourth embodiment has a lower SNR than the first embodiment.

Also, as shown in FIG. 10, comparing the performance at high SNR measured under ITU-R Pedestrian B (speed 3 km / h) channel condition and Vehicular A (speed: 60 km / h) channel condition, an arbitrary mean square From the estimated value of the error, it can be seen that the fourth embodiment shows a lower SNR than the first embodiment.

As described above, according to the method of arranging the pilot layers of the second and fourth layers according to the fourth embodiment, it has a low pilot overhead without showing a lower performance than the first, second and third embodiments. .

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a block diagram of a wireless signal transmission apparatus according to an embodiment of the present invention.

2 is a flowchart illustrating a wireless signal transmission method according to an embodiment of the present invention.

3 is a diagram showing a pilot arrangement according to the first embodiment of the present invention.

4 is a diagram showing a pilot arrangement according to a second embodiment of the present invention.

5 is a diagram showing a pilot arrangement according to a third embodiment of the present invention.

6 is a diagram showing a pilot arrangement according to a fourth embodiment of the present invention.

FIG. 7 is a diagram comparing performance of low SNR measured by applying an average channel estimation method to a pilot layout method of a second layer according to each embodiment of the present invention.

FIG. 8 is a diagram comparing performance at high SNR measured by applying a linear interpolation channel estimation method to a layer 2 pilot arrangement method according to an embodiment of the present invention.

FIG. 9 is a diagram comparing performances of low SNRs measured by applying an average channel estimation method to a pilot layout method of four layers according to each of the first and fourth embodiments of the present invention.

FIG. 10 shows the performance at high SNR measured by applying the average channel estimation method to the pilot arrangement method of the fourth layer according to the first embodiment of the present invention, and the pilot of the fourth layer according to the fourth embodiment of the present invention. This is a comparison of the performance at high SNR measured by applying the channel estimation method of the linear interpolation method to the arrangement method.

Claims (19)

A method of placing a pilot in an uplink frame comprising a tile, Receiving pilot location information from a base station; Selecting a plurality of regions in the tile including a plurality of adjacent symbol sections and a plurality of symbol positions defined by a plurality of adjacent subcarriers; Disposing a pilot corresponding to one layer at one symbol position among the plurality of symbol positions corresponding to each of the plurality of regions based on the pilot position information; And Disposing data at each symbol position except for a symbol position at which the pilot for a plurality of layers is disposed for each of the plurality of regions; Including; The positions of the symbols where the pilots are arranged in the plurality of regions are different from each other so that the pilots are orthogonally arranged between the plurality of layers. Pilot Placement Method. The method of claim 1, Deploying the pilot, Disposing a first pilot corresponding to the one layer at one of a plurality of first symbol positions corresponding to the plurality of symbol positions of a first region of the plurality of regions according to the pilot position information; Disposing a second pilot corresponding to the one layer at one of a plurality of second symbol positions corresponding to the plurality of symbol positions of a second region of the plurality of regions according to the pilot position information; Disposing a third pilot corresponding to the one layer at one of a plurality of third symbol positions corresponding to the plurality of symbol positions of a third region of the plurality of regions according to the pilot position information; And Disposing a fourth pilot corresponding to the one layer at one of a plurality of fourth symbol positions corresponding to the plurality of symbol positions of a fourth region of the plurality of regions according to the pilot position information; The first area is an area adjacent to the first side of the tile and spaced apart from the second side of the tile by a predetermined interval, The second area is an area adjacent to a third side of the tile and spaced apart from the second side of the tile by the predetermined interval, The third area is an area adjacent to the first side of the tile and spaced apart from the fourth side of the tile by the predetermined interval, The fourth area is an area adjacent to the third side of the tile and spaced apart from the fourth side of the tile by the predetermined interval. Pilot Placement Method. The method of claim 2, Deploying the first pilot Arranging the first pilot at a symbol position located at a minimum distance from a first vertex that is an intersection point of the first side and the second side among the plurality of first symbol positions, Deploying the second pilot Arranging the second pilot at a symbol position located at a minimum distance from a second vertex that is an intersection point of the first side and the fourth side among the plurality of second symbol positions, Deploying the third pilot Disposing the third pilot at a symbol position located at a minimum distance from the first vertex of the plurality of third symbol positions, Deploying the fourth pilot Disposing the fourth pilot at a symbol position located at a minimum distance from the second vertex of the plurality of fourth symbol positions; Pilot Placement Method. The method of claim 2, Deploying the first pilot Arranging the first pilot at a symbol position located at a minimum distance from a first vertex which is an intersection point of the first side and the second side among the plurality of first symbol positions, Deploying the second pilot Disposing the second pilot at a symbol position located at a minimum distance from the first vertex of the plurality of second symbol positions, Deploying the third pilot Disposing the third pilot at a symbol position located at a minimum distance from the first vertex among the plurality of third symbol positions, Deploying the fourth pilot Disposing the fourth pilot at a symbol position located at a minimum distance from the first vertex among the plurality of fourth symbol positions; Pilot Placement Method. The method of claim 2, Deploying the first pilot Disposing a null symbol at a remaining one of the plurality of first symbol positions; Deploying the second pilot Disposing a null symbol at a remaining one of the plurality of second symbol positions, Deploying the third pilot Disposing a null symbol at a remaining one of the plurality of third symbol positions; Deploying the fourth pilot Disposing a null symbol at a remaining one of the plurality of fourth symbol positions; Pilot Placement Method. The method of claim 1, And the tile is divided into 10 subcarriers on a frequency axis and 6 symbol intervals on a time axis. Receiving pilot location information from a base station; Selecting a plurality of regions in a tile included in an uplink frame including a plurality of adjacent symbol sections and a plurality of symbol positions defined by a plurality of adjacent subcarriers; Disposing a pilot corresponding to one layer at one symbol position among the plurality of symbol positions corresponding to each of the plurality of regions based on the pilot position information; And Disposing data at each symbol position except for a symbol position at which the pilot for a plurality of layers is disposed for each of the plurality of regions; Including; Between different layers, symbol positions in which the pilots are arranged in the plurality of regions are different from each other, A computer-readable recording medium recording a program for implementing a pilot arrangement method in an uplink frame. The method of claim 7, wherein Deploying the pilot, Placing a first pilot at one of a plurality of first symbol positions adjacent to a first vertex of the tile according to the pilot position information; Disposing a second pilot at one of a plurality of second symbol positions adjacent to a second vertex of the tile according to the pilot position information of the base station; Placing a third pilot at one of a plurality of third symbol positions adjacent to a third vertex of the tile according to the pilot position information of the base station; And Disposing a fourth pilot at one of a plurality of fourth symbol positions adjacent to a fourth vertex of the tile according to pilot position information of the base station; The plurality of first symbol positions are the plurality of symbol positions included in a first region of the plurality of regions, and the plurality of second symbol positions are the plurality of symbol positions included in a second region of the plurality of regions. Wherein the plurality of third symbol positions are the plurality of symbol positions included in a third region of the plurality of regions, and the plurality of fourth symbol positions are the plurality of symbol regions included in a fourth region of the plurality of regions. Symbol location, The plurality of first symbol positions and the plurality of second symbol positions are spaced apart from the first side of the tile by a predetermined interval, and the plurality of third symbol positions and the plurality of fourth symbol positions are the first side. Spaced apart from the second side of the tile facing the predetermined interval Record carrier. The method of claim 8, The disposing of the first pilot may include disposing the first pilot at a symbol position located at a minimum distance from the first vertex among the plurality of first symbol positions. The disposing of the second pilot may include disposing the second pilot at a symbol position located at a minimum distance from the third vertex among the plurality of second symbol positions. The disposing of the third pilot may include disposing the third pilot at a symbol position located at a minimum distance from the first vertex among the plurality of third symbol positions. The disposing of the fourth pilot may include disposing the fourth pilot at a symbol position located at a minimum distance from the third vertex among the plurality of fourth symbol positions. Record carrier. The method of claim 8, The disposing of the first pilot may include disposing the first pilot at a symbol position located at a minimum distance from the first vertex among the plurality of first symbol positions, The disposing of the second pilot may include disposing the second pilot at a symbol position located at a minimum distance from the first vertex among the plurality of second symbol positions, The disposing of the third pilot may include disposing the third pilot at a symbol position located at a minimum distance from the first vertex among the plurality of third symbol positions. The disposing of the fourth pilot may include disposing the fourth pilot at a symbol position located at a minimum distance from the first vertex among the plurality of fourth symbol positions. Record carrier. The method of claim 8, The method of placing the pilot, Disposing a null symbol at a remaining symbol position in each of the plurality of first symbol positions, the plurality of second symbol positions, the plurality of third symbol positions, and the plurality of fourth symbol positions. Record carrier. The method of claim 8, The tile is divided into a plurality of subcarriers in the frequency domain and is divided into a plurality of symbol intervals in the time domain. Record carrier. The method of claim 12, The predetermined interval is the at least one subcarrier Record carrier. delete delete delete delete delete delete

Images