Method and apparatus for receiving signal in integer forcing MIMO system

What is claimed is: 1. A method for receiving a signal in an integer-forcing (IF) Multiple-Input Multiple-Output (MIMO) system, comprising: receiving a plurality of reception signal vectors through a plurality of channels; performing an equalization for the plurality of reception signal vectors; performing a decoding for the plurality of reception signals in which the equalization is performed using a plurality of different reversible integer matrixes; and reconstructing a transmission signal from the reception signal in which the decoding is performed, wherein the step of performing the decoding includes selecting different reversible integer matrixes for each channel block for the plurality of reception signals in which the equalization is performed, wherein the step of selecting different reversible integer matrixes for each channel block includes selecting the reversible integer matrix using a lattice reduction for each channel block, wherein the step of selecting the reversible integer matrix using a lattice reduction for each channel block includes selecting a reversible integer based matrix indicating a coefficient of an integer combination of codewords intended to be decoded for the plurality of reception signals in which the equalization is performed, and wherein the step of selecting the reversible integer matrix using a lattice reduction for each channel block includes inputting a first matrix computed by multiplying an arbitrary value associated with eigenvalue decomposition of the reversible integer matrix and the reversible integer based matrix as an input value of a lattice reduction algorithm, selecting a second matrix corresponding to a lattice reduction operation as an output value of the lattice reduction algorithm, and determining a reversible integer matrix for each channel based on the first and second matrixes. 2. The method for receiving a signal in an IF MIMO system of claim 1 , wherein the step of selecting different reversible integer matrixes for each channel block includes: selecting a reversible integer matrix that minimizes an arithmetic mean of an effective noise variation of an effective noise vector of the channel block. 3. The method for receiving a signal in an IF MIMO system of claim 1 , wherein the step of selecting the reversible integer matrix using a lattice reduction for each channel block includes: inputting a first matrix computed by multiplying an arbitrary value associated with eigenvalue decomposition of the reversible integer matrix and the reversible integer based matrix as an input value of a lattice reduction algorithm; selecting a second matrix corresponding to a lattice reduction operation as an output value of the lattice reduction algorithm; initializing the second matrix using an identity matrix; performing inner product and normalization for a plurality of different column vectors of the first matrix; finding and storing a multiple of a closest modulo value associated with the normalized column vector; performing a multiplication operation for a first column vector of the first matrix based on the stored multiple value and eliminating the same from a second column vector of the first matrix; storing the matrix in which the column elimination operation is performed as a second matrix; and determining a reversible integer matrix for each channel based on the second matrix. 4. The method for receiving a signal in an IF MIMO system of claim 3 , wherein the step of determining a reversible integer matrix for each channel based on the second matrix includes: selecting the plurality of reversible integer matrixes satisfying A 1 =A 2 = . . . =A M mod p (where, A 1 represents a reversible integer matrix, p represents a modulo value, and M represents a number of the plurality of reversible integer matrixes). 5. A signal receiver in an integer-forcing (IF) Multiple-Input Multiple-Output (MIMO) system, comprising: a receiving unit for receiving a plurality of reception signal vectors through a plurality of channels; an equalizing unit for performing an equalization for the plurality of reception signal vectors; a decoding unit for performing a decoding for the plurality of reception signals in which the equalization is performed using a plurality of different reversible integer matrixes; and a signal reconstruction unit for reconstructing a transmission signal from the reception signal in which the decoding is performed, wherein the decoding unit is configured to select different reversible integer matrixes for each channel block for the plurality of reception signals in which the equalization is performed, wherein the decoding unit is configured to select the reversible integer matrix using a lattice reduction for each channel block, wherein the decoding unit is configured to select a reversible integer based matrix indicating a coefficient of an integer combination of codewords intended to be decoded for the plurality of reception signals in which the equalization is performed, and wherein the decoding unit is configured to input a first matrix computed by multiplying an arbitrary value associated with eigenvalue decomposition of the reversible integer matrix and the reversible integer based matrix as an input value of a lattice reduction algorithm, select a second matrix corresponding to a lattice reduction operation as an output value of the lattice reduction algorithm, and determine a reversible integer matrix for each channel based on the first and second matrixes. 6. The signal receiver in an IF MIMO system of claim 5 , wherein the decoding unit is configured to select a reversible integer matrix that minimizes an arithmetic mean of an effective noise variation of an effective noise vector of the channel block. 7. The signal receiver in an IF MIMO system of claim 5 , wherein the decoding unit is configured to input a first matrix computed by multiplying an arbitrary value associated with eigenvalue decomposition of the reversible integer matrix and the reversible integer based matrix as an input value of a lattice reduction algorithm, select a second matrix corresponding to a lattice reduction operation as an output value of the lattice reduction algorithm, initialize the second matrix using an identity matrix, perform inner product and normalization for a plurality of different column vectors of the first matrix, find and store a multiple of a closest modulo value associated with the normalized column vector, perform a multiplication operation for a first column vector of the first matrix based on the stored multiple value and eliminating the same from a second column vector of the first matrix, store the matrix in which the column elimination operation is performed as a second matrix, and determine a reversible integer matrix for each channel based on the second matrix. 8. The signal receiver in an IF MIMO system of claim 7 , wherein the decoding unit is configured to select the plurality of reversible integer matrixes satisfying A 1 =A 2 = . . . =A M mod p (where, A i represents a reversible integer matrix, p represents a modulo value, and M represents a number of the plurality of reversible integer matrixes). 9. An integer-forcing (IF) Multiple-Input Multiple-Output (MIMO) system, comprising: a transmitter for transmitting a plurality of transmission signals through a plurality of channels; and a receiver for receiving a plurality of reception signal vectors through the plurality of channels, performing an equalization for the plurality of reception signal vectors, performing a decoding for the plurality of reception signals in which the equalization is performed using a plurality of different reversible integer matrixes, and reconstructing a transmissio