KR20180072311A - Variable Symbol Detection Method of MIMO Communication System for supporting Multiple Communication Protocol and Quasi-Orthogonal Space Time Block Code - Google Patents

Abstract

Provided is a variable symbol detection method of MIMO communication system for supporting a multiple communication protocol and a quasi-orthogonal space time block code. The variable symbol detection method according to an exemplary embodiment of the present invention includes rearranging an input signal to perform symbol detection by a single hardware according to a transmission matrix defining an input signal in a multiple communication protocol and a corresponding MIMO transmission mode, and calculating a parameter by using an input value set for the MIMO transmission mode. Accordingly, it is possible to reduce hardware complexity and implement flexibility for multiple communication protocol by performing symbol detection by a single hardware for different transmission matrices, and to solve a problem that hardware complexity for symbol detection for a QO-STBC code increases.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a variable symbol detection method for a MIMO communication system capable of supporting multiple communication protocols and quasi-orthogonal spacetime block codes (MIMO communication systems for supporting multiple communication protocols and quasi-orthogonal space time block codes)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a symbol detection apparatus and a method thereof, and more particularly, to a symbol detection apparatus and a method thereof in a multi-antenna (MIMO) communication system having four transmission and reception antennas.

Most of the recently released mobile devices are required to support various communication protocols in order to support multi-band / multi-mode. Thus, a variable symbol detector capable of supporting multiple protocols is required.

In the current MIMO-based wireless communication system standard, an orthogonal space-time block code (O-STBC) capable of full-rate and maximum diversity gain for supporting a diversity transmission mode capable of improving reception performance, Time Block Code).

In general, in a multi-antenna system, a larger diversity gain can be obtained as the number of antennas increases, but when there are more than two transmission antennas, there is no orthogonal coding matrix with a full-rate of 1 .

For this reason, quasi-orthogonal space-time block coding (QO-STBC) is proposed to reduce the loss in the diversity gain so that the coding rate becomes 1 when the number of transmission antennas is three or more. However, There is a disadvantage in that a large amount of computation and an increase in implementation complexity occur in detection.

Recently, in the case of using three or more transmission antennas in the wireless communication standard, a transmission matrix is defined as a symbol detection capable of symbol detection only by a simple linear operation at the receiving end (see the transmission matrix defined for four transmission antennas) (1) full-rate support and diversity gain (2) as in the case of two transmit antennas.

However, the QO-STBC transmission matrix supports diversity gain of 2 to 4 or less due to the additional coding gain, and the reception performance is usually better by about 2 dB. In order to improve the performance of the wireless communication channel environment, various next-generation wireless communication standards consider support for a QO-STBC transmission matrix with a relatively high coding gain and diversity gain, It is imperative to solve the computational complexity problem for symbol detection.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problem of performance and implementation complexity of a MIMO symbol scheme for a mobile device supporting multi-band / multi-mode, Protocol and a symbol detection method for a QO-STBC code capable of improving performance with high diversity gain without additional hardware increase.

According to an aspect of the present invention, there is provided a symbol detection method comprising: rearranging a transmission matrix defining an input signal in a multiple communication protocol and symbols detectable by a single hardware according to a corresponding MIMO transmission mode; And calculating a parameter using an input value set for the MIMO low-concentration mode.

In the reordering step, an input terminal of the PCM required can be set according to the MIMO transmission mode by receiving the channel coefficient and the received symbol.

In addition, the reordering step may switch the column vectors of the input channel so that the operation block can be shared through the multi-stage implementation when operating in the spatial multiplexing mode.

And calculating the LLR using the DVCM and the 1 DCM using the parameter in the diversity mode.

The method may further include calculating the Euclidean distance through the X2CCM and the EDCM in the case of the spatial multiplexing mode (MIMO-SM) and the QO-SFBC / STBC mode.

And summing all the Euclidean distance values in the QO-SFBC / STBC mode.

The method may further include calculating LLRs in 1 DCM and 2DCM after Euclidean distance calculation.

Meanwhile, according to another embodiment of the present invention, a symbol detection apparatus includes an input preprocessor module (IPM) that rearranges a transmission matrix defining an input signal in a multiple communication protocol and symbols to be detected by a single hardware according to a corresponding MIMO transmission mode; And a parameter calculation module (PCM) for calculating a parameter using an input value set for the MIMO low concentration mode.

As described above, according to the embodiments of the present invention, it is possible to detect symbols in a single hardware for different transmission matrices, thereby reducing hardware complexity and securing flexibility for multiple communication protocols.

Further, according to the embodiments of the present invention, it is possible to solve the problem of hardware complexity increase for symbol detection for the QO-STBC code.

1 shows a diversity transmission matrix defined in a communication standard,
2 is a diagram illustrating a hardware structure of a variable MIMO symbol detector according to an embodiment of the present invention.
FIG. 3 is a simplified version of the hardware structure shown in FIG. 2,
FIG. 4 is a diagram illustrating a symbol detection process by the variable MIMO symbol detector shown in FIG. 2;
5 to 9 are block diagrams of a variable symbol detector according to an embodiment of the present invention, which are used for each MIMO mode.

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

The variable symbol detector according to the embodiment of the present invention supports all the transmission matrices defined in the multiple communication standard shown in the table of FIG. 1 through a single hardware, and the antenna configuration from the minimum (1x1) to the maximum (4x4) .

In addition, the variable symbol detector according to the embodiment of the present invention can be applied to a spatial multiplexing (MIMO-SM) technique for increasing a transmission rate and a MIMO-SD technique for improving performance, a MIMO- QO-STBC / SFBC technology can be supported.

2 is a diagram illustrating a hardware structure of a variable MIMO symbol detector according to an embodiment of the present invention.

2, a variable MIMO symbol detector according to an embodiment of the present invention includes a CHPM (channel preprocessor module) 100, an IPM (input preprocessor module) 210, a PCM (parameter calculation module) 220, A decision variable calculation module (DVCM) 230, an X2C calculation module 240, an Euclidean distance calculation module (EDCM) 250, an Euclidean distance summation module (EDSM) 260, a 1D LLR calculation module ) 270, a 2D LLR calculation module 280, a quantization module (QM) 290, and a gated clock generation module (GCGM)

3 is a simplified view of the hardware structure shown in FIG. 3, the variable MIMO symbol detector according to an exemplary embodiment of the present invention includes a CHPM 100 and a 2x4 core detector 200. The 2x4 core detector 200 includes a 2x4 core detector 200, And all the blocks except for the CHPM 100 and the GCGM 300 are included.

FIG. 4 is a diagram illustrating a symbol detection process by the variable MIMO symbol detector shown in FIG. 2. Referring to FIG.

4, a 4x4 channel matrix and a 4x1 reception signal vector, which are two input signals, are input to the IPM 210, which is the input terminal of the 2x4 core detector 200, according to the MIMO transmission mode through the CHPM 100, And output as a 4x2 channel matrix and a 4x1 reception signal vector, respectively (Step 1 and 2).

These two input vectors are rearranged according to the transmission matrix defined in the multiple communication protocol and the corresponding MIMO transmission mode through the IPM 210 (step 3), and the parameters p1, p2, p3 are calculated through the PCM 220 Step 4).

At this time, the IPM 210 receives the channel coefficient and the received symbol, and sets the input terminal of the PCM 220 according to the MIMO transmission mode. That is, it includes a function of switching a column vector of an input channel so that operation block can be shared through multi-stage implementation when operating in a spatial multiplexing mode.

In the case of the diversity mode, the LLR calculation is performed through the DVCM 230 and the 1 DCM 270 using these three parameters. In the case of the spatial multiplexing mode (MIMO-SM) and the QO-SFBC / STBC mode, 240 and the EDCM 250 to calculate the Euclidean distance. In this case, in the case of the QO-SFBC / STBC mode, the EDSM 250 is additionally required since the Euclidean distance values must be added (step 5-8). However, it does not have a large effect on the total complexity of the proposed MIMO symbol detector, which is composed only of adder circuits. In addition, the complexity is reduced without performance degradation by approximating the norm computation.

After the Euclidean distance calculation, the LLR is calculated (step 8) in the 1DCM 270 and the 2DCM 280 (step 9), and the LLR value is quantized 8 bits in the QM 290 (step 9).

Here, the QO-SFBC / STBC transmission mode is basically implemented by sharing the operation blocks used for symbol detection in the spatial multiplexing transmission mode.

The above equation represents a metric for ML symbol detection of a symbol to which the QO-SFBC / STBC transmission matrix is applied. However, in the embodiment of the present invention, it is possible to share calculation blocks by deriving the symbols used for symbol detection for the 2x4 MIMO-SM transmission mode.

5 to 9 show a process of supporting various antenna configurations and MIMO transmission modes through the CHPM 100 and the 2x4 core detector 200. FIG. It is divided into five modes. The blocks used are indicated in yellow according to the mode. Diversity transmission mode. Hybrid transmission mode. QO-STBC transmission mode, 2x2 / 2x4 spatial multiplexing transmission mode, and 4x4 spatial multiplexing transmission mode.

Up to now, a variable symbol detection method capable of supporting multiple protocols has been described in detail with a preferred embodiment.

The variable symbol detection method according to an embodiment of the present invention is capable of variably detecting symbol detection for all diversity transmission matrices of a wireless communication standard by a single hardware and supports various communication protocols and supports a maximum coding rate and an additional diversity Symbol detection for QO-STBC code, which can improve performance with gain, is possible by sharing calculation block for MIMO mode support without increasing hardware.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the present invention.

100: channel preprocessor module (CHPM)
200: 2x4 Core Detector (2x4 Core Detector)
210: IPM (input preprocessor module)
220: parameter calculation module (PCM)
230: a decision variable calculation module (DVCM)
240: X2CM (X2C calculation module)
250: Euclidean distance calculation module (EDCM)
260: Euclidean distance summation module (EDSM)
270: 1D LLR calculation module (DCM)
280: 2D LLR calculation module (2DCM)
290: Quantization module (QM)
300: gated clock generation module (GCGM)

Claims (8)

Rearranging the input signal to enable symbol detection with a single hardware for a transmission matrix defined in multiple communication protocols and a corresponding MIMO transmission mode;
And calculating a parameter using an input value set for the MIMO low concentration mode.
The method according to claim 1,
In the reordering step,
Receiving a channel coefficient value and a received symbol as input, and setting an input terminal of a required PCM according to a MIMO transmission mode.
The method of claim 2,
In the reordering step,
Wherein a column vector of the input channel is switched so that the operation block can be shared through a multi-stage implementation when operating in the spatial multiplexing mode.
The method according to claim 1,
Calculating a LLR using a DVCM and a 1DCM using a parameter in case of a diversity mode.
The method according to claim 1,
Calculating a Euclidean distance through X2CCM and EDCM in a spatial multiplexing mode (MIMO-SM) and a QO-SFBC / STBC mode.
The method of claim 5,
And summing the Euclidean distance values in the QO-SFBC / STBC mode.
According to claim 6,
And calculating LLRs in 1 DCM and 2DCM after Euclidean distance calculation.
An input preprocessor module (IPM) that rearranges the input signal to define a transmission matrix defining multiple communication protocols and symbol detection with a single hardware for the corresponding MIMO transmission mode;
And a parameter calculation module (PCM) for calculating a parameter using an input value set for the MIMO low concentration mode.

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