Symmetric and full duplex relay in wireless systems

What is claimed is: 1. A method for Multiple Input Multiple Output (MIMO) wireless communication systems comprising beamforming two or more spatial multiplexed streams, by a Base Station (BS) with a plural of antennas with two or more antennas on User Equipment (UEs) wherein each UE has a sufficient number of antennas to receive and/or transmit one or more spatial multiplexed streams, using one or more relays, whose total number of antennas is sufficient to support the two or more spatial multiplexed streams and whose Downlink (DL) and Uplink (UL) Radio Frequency (RF) circuit paths are symmetric with closely matched transfer functions, to project the capacity of the BS to cover one or more UEs, estimating, by the BS, the uplink Channel State Information (C SI) between each antenna on the BS and each antenna on the one or more UEs using pilots transmitted from the UE antennas in the presence of the relays which amplifies and forwards the one or more pilots; and, making use of, by the BS, the perseverance of the reciprocity of the over the air channel by the symmetry of the DL and UL RF circuit paths of the one or more relays to obtain the downlink Total Channel CSI using the estimated uplink Total Channel CSI that includes the effect of the relays. 2. The method in claim 1 wherein the relay has N BF ≥2 antennas for receiving signals from the BS or other relays in the downlink and transmitting signals in the uplink and has N UF ≥2 antennas for transmitting signals in the downlink and receiving signals from the UEs and/or other relays in the uplink. 3. The method in claim 1 further comprising that using adjustable components such as attenuators and/or phase shifters in the DL and UL paths, by an relay, to make the circuit response of the DL path and the circuit response of the UL path the same or approximately the same to achieve the symmetry of the DL and UL paths. 4. The method in claim 3 further comprising adjusting the parameters of the adjustable components according to a measurement signal transmitted and received by the relay in a special reserved time slot. 5. The method in claim 1 further comprising an active interference cancellation block to enhance the isolation between a pair of receiving and transmitting antennas. 6. The method in claim 5 wherein the active interference cancellation block includes a circuit for estimating the over the air channel between a pair of transmitting and receiving antennas and using the estimated channel and a sampling of the transmitted signal to generate a cancelation signal. 7. The method in claim 6 wherein the circuit of the active interference cancellation block includes one or more of attenuator, phase shifter, Analog-to-Digital Converter (ADC), down-conversion, and signal generator. 8. The method in claim 7 further comprising adjusting the parameters of the attenuators and phase shifters according to a measurement signals transmitted and received by the relay in a special reserved time slot for tuning the circuit of the active interference cancellation block. 9. The method in claim 1 wherein the DL path and UL path shares the same amplify-and-forward path, switches to change the direction of signal transmission, and a control signal processing block. 10. The method in claim 9 wherein the control signal processing block generates control signals to change the connections of the switches. 11. The method in claim 10 wherein the control signal processing block detects and decodes the message about the DL and UL transmission indication and generates corresponding control signals to change the connections of the switches. 12. The method in claim 10 wherein the control signal processing block detects the signal power strength to decide the DL and UL transmission mode and generates corresponding control signals to change the connections of the switches. 13. The method in claim 12 wherein the power detection and switching control is completed in a short period of time not affecting the signal detection at the receiver. 14. The method in claim 13 wherein the short period of time is within a fraction of the Cyclic Prefix (CP) in an OFDM symbol. 15. A relay to enhance a MIMO wireless communication system comprising one or more pairs of a DL circuit path and an UL circuit path to amplify and forward two or more spatial multiplexed streams between a BS with a plural of antennas and two or more antennas on UEs wherein each UE has a sufficient number of antennas to receive and/or transmit the spatial multiplexed streams intended for it, and each path containing one or more adjustable circuit components; a measurement signal generator that transmits a measurement signal and a receiver that receives the measurement signal and measures the circuit response of the DL and UL circuit paths of the relay, and, a control circuit that generates the adjustment needed and changes the settings of the one or more adjustable circuit components to bring the circuit response of the DL and UL circuit paths of the relay to be the same or approximately the same; wherein the relay further comprises having N BF ≥2 antennas for receiving signals from the BS or other relays in the downlink and transmitting signals in the uplink and has N UF ≥2 antennas for transmitting signals in the downlink and receiving signals from the UEs and/or other relays in the uplink. 16. A relay to enhance a TDD MIMO wireless communication system comprising one or more amplify-and-forward paths to amplify and forward two or more spatial multiplexed streams between a BS with a plural of antennas and two or more antennas on UEs wherein each UE has a sufficient number of antennas to receive and/or transmit the spatial multiplexed streams intended for it; symmetric traces and switches to switch the one or more amplify-and-forward circuit paths of the relay to the DL direction when the BS is sending DL signal and to the UL direction when the BS is receiving UL signal such that the circuit responses in the two switched directions are the same or approximately the same; and a control circuit that detects the wireless signal direction using the RF signal it receives and switches the one or more amplify-and-forward circuit paths of the relay to match the direction of the direction of the wireless signals in the TDD MIMO wireless communication system. 17. The relay in claim 16 wherein the control circuit detects and decodes the message about the DL and UL transmission indication and generates corresponding control signals to change the one or more amplify-and-forward paths to match the direction of the direction of the wireless signals in the TDD MIMO wireless communication system. 18. The method in claim 16 wherein the control circuits detects the signal power strength to decide the DL and UL transmission mode, generates corresponding control signals to change the one or more amplify-and-forward paths to match the direction of the direction of the wireless signals in the TDD MIMO wireless communication system, and completes the change in a short period of time not affecting the signal detection at the receiver.