Wireless receiving apparatus and method thereof

The invention claimed is: 1. A wireless receiving apparatus comprising: at least one beamforming weight generator configured to: generate an N′×B′ weight matrix W whose columns are orthogonal to each other by decomposing an estimated N′×M′ channel matrix, defined between M′ transmitting antennas of one or more wireless transmitting apparatuses and N′ receiving antennas coupled to the wireless receiving apparatus, into the N′×B′ weight matrix W and a B′×M′ matrix containing two or more non-zero matrix elements in each column, wherein B′ is an integer less than or equal to N′−1 and greater than or equal to M′; or generate a combination of an N′×B′ sub-weight matrix W 1 and at least one second sub-weight matrix, wherein a product of the sub-weight matrix W 1 with the at least one second sub-weight matrix is equal to the weight matrix W; a first beamformer configured to perform receive beamforming on received signals of the N′ receiving antennas using the weight matrix W or the sub-weight matrix W 1 ; and a belief propagation (BP) detector configured to perform a BP algorithm using signals output from the first beamformer and transmitted through a fronthaul. 2. The wireless receiving apparatus according to claim 1 , comprising a Radio Unit (RU) and a Distributed Unit (DU) connected to each other via the fronthaul, wherein the first beamformer is included in the RU, the BP detector is included in the DU, and the at least one beamforming weight generator is included in at least one of the RU and the DU. 3. The wireless receiving apparatus according to claim 1 , wherein the receive beamforming includes taking a product of a Hermitian conjugate of the weight matrix W or of the sub-weight matrix W 1 with a received signal vector composed of the received signals of the N′ receiving antennas. 4. The wireless receiving apparatus according to claim 1 , further comprising a second beamformer, wherein the at least one beamforming weight generator is configured to generate a combination of the sub-weight matrix W 1 and a B′×B′ sub-weight matrix W 2 , the product of which is equal to the weight matrix W, and to provide the sub-weight matrix W 1 to the first beamformer and the sub-weight matrix W 2 to the second beamformer, the first beamformer is configured to perform receive beamforming by taking a product of a Hermitian conjugate of the sub-weight matrix W 1 with a received signal vector composed of the received signals of the N′ receiving antennas, the second beamformer is configured to perform receive beamforming by taking a product of a Hermitian conjugate of the sub-weight matrix W 2 with signals output from the first beamformer and transmitted via the fronthaul, and to provide beamformed signals to the BP detector, and the BP detector is configured to perform the BP algorithm on the signals supplied from the second beamformer. 5. The wireless receiving apparatus according to claim 4 , wherein the BP detector includes an initial value generator, wherein the initial value generator is configured to: generate, as a soft replica and soft replica power, a soft decision value for a product of a Hermitian conjugate of a B′×M′ initial value generation matrix and the receive-beamformed received signals provided from the first beamformer; and provide the soft replica and soft replica power to the first iteration of the BP algorithm performed by the BP detector, the sub-weight matrix W 1 is an N′×M′ matrix composed of left singular vectors obtained by singular value decomposition of the N′×M′ channel matrix, the sub-weight matrix W 2 is an arbitrary M′-order unitary matrix, and the initial value generating matrix is a product of an M′-order diagonal matrix whose diagonal components are inverse values of singular values obtained by the singular value decomposition, with a Hermitian conjugate of an M′-order square matrix composed of right singular vectors. 6. The wireless receiving apparatus according to claim 4 , wherein the BP detector includes an initial value generator, wherein the initial value generator is configured to: generate, as a soft replica and soft replica power, a soft decision value for a product of a Hermitian conjugate of a B′×M′ initial value generation matrix and the receive-beamformed received signals provided from the first beamformer; and provide the soft replica and soft replica power to the first iteration of the BP algorithm performed by the BP detector, the sub-weight matrix W 1 is the N′×M′ channel matrix, the sub-weight matrix W 2 is a −½ power of a product of a Hermitian conjugate of the channel matrix with the channel matrix, and the initial value generating matrix is an inverse matrix of the product of the Hermitian conjugate of the channel matrix with the channel matrix. 7. The wireless receiving apparatus according to claim 1 , wherein the at least one beamforming weight generator is configured to: divide the N′×M′ channel matrix into K N′ k ×M′ sub-matrices; decompose each sub-matrix into an N′ k ×B′ k matrix W k whose columns are orthogonal to each other and a B′ k ×M′ matrix containing two or more non-zero matrix elements in each column, wherein the smaller of N′ k and M′ is B′ k ; and output, as the weight matrix W, a block diagonal matrix having the matrix W k as a diagonal component. 8. The wireless receiving apparatus according to claim 1 , wherein the at least one beamforming weight generator is configured to: output, as the weight matrix W, a product of an N′×M′ Q-matrix obtained by QR-decomposing the N′×M′ channel matrix with an M′-order unitary matrix; or output the Q-matrix as the sub-weight matrix W 1 and the M′-order unitary matrix as the sub-weight matrix W 2 . 9. The wireless receiving apparatus according to claim 1 , wherein the at least one beamforming weight generator is configured to: output, as the weight matrix W, an N′×M′ matrix composed of left singular vectors obtained by singular value decomposition of the N′×M′ channel matrix; or output, as the weight matrix W, a product of the N′×M′ matrix and an M′-order unitary matrix; or output the N′×M′ matrix as the sub-weight matrix W 1 and the M′-order unitary matrix as the sub-weight matrix W 2 . 10. The wireless receiving apparatus according to claim 1 , wherein the at least one beamforming weight generator is configured to: output, as the weight matrix W, a product of the N′×M′ channel matrix and a −½ power of a Gram matrix of the N′×M′ channel matrix; or output the channel matrix as the sub-weight matrix W 1 and the −½ power of the Gram matrix as the sub-weight matrix W 2 ; or output the channel matrix as the sub-weight matrix W 1 and a product of the −½ power of the Gram matrix with an M′-order unitary matrix as the sub-weight matrix W 2 ; or output a product of the channel matrix with the −½ power of the Gram matrix as the sub-weight matrix W 1 and an M′-order unitary matrix as the sub-weight matrix W 2 . 11. The wireless receiving apparatus according to claim 1 , further comprising at least one memory configured to store a first parameter set including a plurality of scaling factors and a plurality of damping factors or a second parameter set including a plurality of scaling factors and a plurality of weight factors, wherein the BP detector is configured to perform a Gaussian Belief Propagation (GaBP) algorithm using the first parameter set or the second parameter set, and the BP detector comprises: a soft interference canceller configured to, using replicas of all transmitted signals except an m′-th transmitted signal generated in a (t−1)th iteration, subtract components of the all transmitted signals except a component of the m′-th t