SHAPING mmWAVE WIRELESS CHANNEL VIA MULTI-BEAM DESIGN USING RECONFIGURABLE INTELLIGENT SURFACES

What is claimed is: 1 . A method for shaping a millimeter wave (mmWave) wireless channel in a wireless network, the method comprising: enabling communication between a multi-antenna transmitter and a multi-antenna receiver, the multi-antenna receiver being a plurality of mobile devices of a plurality of users; positioning a reconfigurable intelligent surface (RIS) in a vicinity of the multi-antenna transmitter and the multi-antenna receiver, the RIS reflecting signals received from the multi-antenna transmitter toward the multi-antenna receiver; constructing the RIS as a uniform planar array (UPA) structure forming a multi-beamforming framework, a surface of the UPA defining an array of discrete elements arranged in a grid pattern, wherein parameters of the discrete elements of the UPA are controllable to achieve multiple disjoint beams covering different solid angles; and enabling the plurality of users of the plurality of mobile devices positioned in blind spots of a coverage map to communicate with the multi-antenna transmitter by employing the RIS to generate sharp and effective beams having almost uniform gain in a desired angular coverage interval (ACI). 2 . The method of claim 1 , wherein channel matrices of each discrete element of the UPA of the RIS are given as: H t =d M t {Ω t }ρ t d M H {Ω 1 }, and H r =d M {Ω 2 }ρ r d M r H {Ω r }, where Ω t and Ω 2 are solid angles of departure (AoD) of beams transmitted from the multi-antenna transmitter and the RIS, Ω 1 and Ω r are solid angles of arrival (AoA) of the beams received at the RIS and the multi-antenna receiver, respectively, a gain of the line-of-sight (LoS) paths from the transmitter to the RIS and from the RIS to the receiver are denoted by ρ t and ρ r , respectively, and d M t , d M , d M H , and d M r H , denotes various directivity vectors defining distances between the discrete elements of the UPA of the RIS. 3 . The method of claim 1 , wherein a beamforming vector is defined as: c =[ c 0,0 , . . . ,c 0,M h-1 ,c 1,0 , . . . ,c M v-1 ,M h-1 ] wherein values of the phase shift θ k and the attenuation value β k for the k th elements of the RIS are found by using corresponding beamforming coefficient c k and a value of the k th element of a directivity vector d M {Ω 1 } for any receive incident solid angle Ω 1 . 4 . The method of claim 1 , wherein the sharp and effective beams depend on solid angles at which incident waves from the multi-antenna receiver activate the discrete elements of the UPA. 5 . The method of claim 1 , wherein the RIS is a passive RIS where both phase control and gain control are permitted. 6 . The method of claim 1 , wherein values for a phase shift and an attenuation value of the RIS are determined by using corresponding beamforming coefficients and a value of a kth element of a directivity vector for any receive incident solid angle. 7 . The method of claim 1 , wherein the multi-beamforming framework is designed as an optimization problem. 8 . A non-transitory computer-readable storage medium comprising a computer-readable program for shaping a millimeter wave (mmWave) wireless channel in a wireless network, wherein the computer-readable program when executed on a computer causes the computer to perform the steps of: enabling communication between a multi-antenna transmitter and a multi-antenna receiver, the multi-antenna receiver being a plurality of mobile devices of a plurality of users; positioning a reconfigurable intelligent surface (RIS) in a vicinity of the multi-antenna transmitter and the multi-antenna receiver, the RIS reflecting signals received from the multi-antenna transmitter toward the multi-antenna receiver; constructing the RIS as a uniform planar array (UPA) structure forming a multi-beamforming framework, a surface of the UPA defining an array of discrete elements arranged in a grid pattern, wherein parameters of the discrete elements of the UPA are controllable to achieve multiple disjoint beams covering different solid angles; and enabling the plurality of users of the plurality of mobile devices positioned in blind spots of a coverage map to communicate with the multi-antenna transmitter by employing the RIS to generate sharp and effective beams having almost uniform gain in a desired angular coverage interval (ACI). 9 . The non-transitory computer-readable storage medium of claim 8 , wherein channel matrices of each discrete element of the UPA of the RIS are given as: H t =d M t {Ω t }ρ t d M H {Ω 1 }, and H r =d M {Ω 2 }ρ r d M r H {Ω r }, where Ω t and Ω 2 are solid angles of departure (AoD) of beams transmitted from the multi-antenna transmitter and the RIS, Ω 1 and Ω r are solid angles of arrival (AoA) of the beams received at the RIS and the multi-antenna receiver, respectively, a gain of the line-of-sight (LoS) paths from the transmitter to the RIS and from the RIS to the receiver are denoted by ρ t and ρ r , respectively, and d M t , d M , d M H , and d M r H denotes various directivity vectors defining distances between the discrete elements of the UPA of the RIS. 10 . The non-transitory computer-readable storage medium of claim 8 , wherein a beamforming vector is defined as: c =[ c 0,0 , . . . ,c 0,M h-1 ,c 1,0 , . . . ,c M v-1 ,M h-1 ] wherein values of the phase shift θ k and the attenuation value β k for the k th elements of the RIS are found by using corresponding beamforming coefficient c k and a value of the k th element of a directivity vector d M {Ω 1 } for any receive incident solid angle Ω 1 . 11 . The non-transitory computer-readable storage medium of claim 8 , wherein the sharp and effective beams depend on solid angles at which incident waves from the multi-antenna receiver activate the discrete elements of the UPA. 12 . The non-transitory computer-readable storage medium of claim 8 , wherein the RIS is a passive RIS where both phase control and gain control are permitted. 13 . The non-transitory computer-readable storage medium of claim 8 , wherein values for a phase shift and an attenuation value of the RIS are determined by using corresponding beamforming coefficients and a value of a kth element of a directivity vector for any receive incident solid angle. 14 . The non-transitory computer-readable storage medium of claim 8 , wherein the multi-beamforming framework is designed as an optimization problem. 15 . A system for shaping a millimeter wave (mmWave) wireless channel in a wireless network, the system comprising: a memory; and one or more processors in communication with the memory configured to: enable communication between a multi-antenna transmitter and a multi-antenna receiver, the multi-antenna receiver being a plurality of mobile devices of a plurality of users; position a reconfigurable intelligent surface (RIS) in a vicinity of the multi-antenna transmitter and the multi-antenna receiver, the RIS reflecting signals received from the multi-antenna transmitter toward the multi-antenna receiver; construct the RIS as a uniform planar array (UPA) structure forming a multi-beamforming framework, a surface of the UPA defining an array of discrete elements arranged in a grid pattern, wherein parameters of the discrete elements of the UPA are controllable to achieve multiple disjoint beams covering different solid angles; and enable the plurality of users of the plurality of mobile devices positioned in blind