Method and a system for dynamic association of spatial layers to beams in millimeter-wave fixed wireless access networks

The invention claimed is: 1. A method to dynamically associate spatial layers to beams in a Fixed Wireless Access (FWA) network operating in a millimeter-wave frequency range, wherein a base station and at least one customer premises equipment (CPE) are configured to wirelessly transmit and receive data through a wireless channel of said FWA network, said base station having beamforming capabilities to generate multiple wireless beams, the method comprising: performing, by the base station, all baseband wireless functions related for creating, keeping and managing connections between the base station and the at least one CPE at baseband level, wherein information is handled in a form of up to M spatial layer signals that are transmitted/received by a multi-beam antenna array of the base station and with no built-in capabilities for creation, detection or management of the beams; performing, by the base station, all radio frequency (RF) functions at millimeter-wave frequencies, including beamforming and conversion from complex baseband signals to RF signals and vice versa, in such a way that a fully flexible association between spatial layers and beams is possible, to allow any spatial layer to be transmitted/received by any beam at a per-user level; and coupling, by the base station, the RF signals to said wireless channel and vice versa, wherein an initial access of the at least one CPE to the base station is handled by a baseband processor subsystem of the base station by: sending, by the base station, beacon signals through available beams; receiving, by the base station, a request from the at least one CPE that detects said beacon signals, requesting a connection to the base station through any of the available beams; estimating, as a preferred beam, by the base station, a beam from which most energy is detected in uplink, and connecting a group of antenna elements involved in reception of said preferred beam to an input of an spatial layer of said baseband processor subsystem; and detecting, by the baseband processor subsystem, a user identification (user ID), corresponding to received uplink data, and associating the user ID to said preferred beam using a table that contains an association between active CPEs and beams throughout a lifetime of the connection. 2. The method of claim 1 , wherein said user ID is a Medium Access Control (MAC) address of the at least one CPE. 3. The method of claim 1 , wherein the baseband processor subsystem is configured to handle downlink transmissions to the at least one CPE, the at least one CPE being in connected mode, by first checking in the table the preferred beam corresponding to the user ID to be addressed, and then by forwarding a beam indicator to a beam switching subsystem at the base station, the beam switching subsystem being configured to, upon reception of said beam indicator, connect spatial layer signals involved in a downlink transmission with the group of antenna elements corresponding to said preferred beam. 4. The method of claim 1 , wherein more than one CPE are active at the same time and the baseband processor subsystem is configured to handle downlink transmissions to active CPEs in connected mode by checking the preferred beam corresponding to each active CPE and by forwarding a beam indicator for each active CPE to a beam switching subsystem, the beam switching subsystem being configured to, upon reception of beam indicators, connect spatial layer signals involved in a downlink transmission with the group of antenna elements corresponding to each preferred beam. 5. The method of claim 1 , wherein the baseband processor subsystem is configured to handle uplink transmissions from the at least one CPE, the at least one CPE being in connected mode, by: based on the base station comprising a radio resource scheduler in charge of allocating radio resources to the at least one CPE, providing, by said baseband processor subsystem, at least one beam indicator to a beam switching subsystem at the base station in order to activate the preferred beam for uplink reception corresponding to the user ID included in the table, including an ability to activate more than one beam based on the base station supporting Multi-user-Multiple Input Multiple Output (MU-MIMO), and several CPEs located at different beams transmitting at the same time; or based on the base station not comprising the radio resource scheduler, detecting, by the base station, a preferred beam for uplink connected mode according to a physical location of the at least one CPE, and providing a beam indicator to the beam switching subsystem for connecting outputs from M groups of antennas corresponding to said preferred beam for uplink connected mode to the M spatial layer signals that are input to the baseband processor subsystem. 6. The method of claim 5 , wherein said M spatial layer signals are either coherently combined by the baseband processor subsystem with Maximal Ratio Combining (MRC), or Interference Rejection Combining (IRC), to reinforce detection in a case of a single-layer transmission by the at least one CPE, or jointly decoded to perform spatial de-multiplexing of layers, in a case of a multi-layer transmission by the at least one CPE. 7. The method of claim 5 , wherein said preferred beam for uplink connected mode is detected by: detecting, by the base station, strongest energy at outputs of a plurality of Low-Noise Amplifiers (LNAs) of the M spatial layer signals, and assigning a beam detected with the strongest energy to the preferred beam for uplink connected mode; obtaining, by the baseband processor subsystem, the user ID after decoding an uplink packet, and comparing the preferred beam stored in the table with the preferred beam for uplink connected mode; and discarding, by the baseband processor subsystem, said uplink packet based on a mismatch between the preferred beam for uplink connected mode and the preferred beam stored in the table for the same user ID. 8. The method of claim 7 , wherein the beam switching subsystem is configured to, upon receiving the beam indicator, connect the outputs from the M groups of antennas corresponding to said preferred beam with the M spatial layer signals that are input to the baseband processor subsystem. 9. A system to dynamically associate spatial layers to beams in a Fixed Wireless Access (FWA) network operating in a millimeter-wave frequency range, said system comprising a base station and at least one customer premises equipment (CPE) configured to wirelessly transmit and receive data through a wireless channel of said FWA network, said base station having beamforming capabilities and configured to generate multiple wireless beams, wherein said base station comprises: a baseband processor subsystem configured to perform all baseband wireless functions related to creating, keeping and managing connections between the base station and the at least one CPE at baseband level, wherein information is handled in a form of up to M spatial layer signals that are transmitted/received by a multi-beam antenna array of the base station, and with no built-in capabilities for creation, detection or management of the beams; a radio-frequency (RF) frontend subsystem configured to perform all RF functions at millimeter-wave frequencies, including beamforming and conversion from complex baseband signals to RF signals and vice versa, in such a way that a fully flexible association between spatial layers and beams is possible, to allow any spatial layer to be transmitted/received by any beam at a per-user level; said multi-beam antenna array configured to couple the RF signals to said wireless channel and vice versa, and comprising a collection of N antenna elements configured t