Over-the-air channel state information acquirement for a massive MIMO channel emulator with over-the-air connection

We claim: 1. A method for testing a multi-user multiple input multiple output (MU-MIMO) wireless communication system comprising: creating an over-the-air (OTA) connection between antennas of a base station (BS) with M>2 transmitting or receiving paths or antennas and a channel emulator with N>2 transmitting or receiving paths or antennas; transmitting pilot signals between the M transmitting paths or antennas of the BS and the channel emulator for estimating an N×M channel matrix G between the BS and the channel emulator wherein the pilot signal transmitted from each transmitting path or antenna is made to be separable from the pilot signals transmitted from other transmitting paths or antennas; receiving the pilot signals, processing the received pilot signals to separate out the pilot signal transmitted by each transmitting path or antenna, and using the pilot signals to estimate the channel matrix G representing the channels between the BS and the channel emulator; wherein the method further comprises the channel emulator using the estimated channel matrix G to equalize the channel between the BS and the channel emulator when performing emulation of the channels between the BS and a plurality of UEs in MU-MIMO communication. 2. The method in claim 1 wherein the transmitting and receiving paths of the BS are calibrated to achieve MU-MIMO beamforming. 3. A method for testing a multi-user multiple input multiple output (MU-MIMO) wireless communication system comprising: creating an over-the-air (OTA) connection between antennas of a base station (BS) with M>2 transmitting or receiving paths or antennas and a channel emulator with N>2 transmitting or receiving paths or antennas; transmitting pilot signals between the M transmitting paths or antennas of the BS and the channel emulator for estimating an N×M channel matrix G between the BS and the channel emulator wherein the pilot signal transmitted from each transmitting path or antenna is made to be separable from the pilot signals transmitted from other transmitting paths or antennas; receiving the pilot signals, processing the received pilot signals to separate out the pilot signal transmitted by each transmitting path or antenna, and using the pilot signals to estimate the channel matrix G representing the channels between the BS and the channel emulator; wherein the method further comprises calibrating transmitting and receiving paths of the channel emulator to account for the non-reciprocity of a transmitting circuit and a receiving circuit of the channel emulator so that the channel emulator achieves reciprocity in a downlink channel and uplink channel to model the reciprocal OTA channel between the BS and a plurality of user equipment (UEs) in a Time-Division Duplex (TDD) system. 4. The method in claim 3 further comprising obtaining the estimate of the channel matrix between the BS and the channel emulator in one direction, either downlink or uplink, from the estimate of the channel matrix in the opposite direction by making use of the reciprocity of the channel in a TDD system. 5. The method in claim 1 further comprising transmitting pilot signals in both downlink and uplink directions to obtain the estimate of the channel matrix G between the BS and the channel emulator in the two directions in a Frequency-Division Duplex (FDD) system. 6. The method in claim 1 wherein equalizing the channel between the BS and the channel emulator is achieved by applying a compensation matrix to equalize the effect of the G matrix such that the channel emulator effectively emulates specified channel models between the M transmitting or receiving paths or antennas of the BS and K≥2 transmitting or receiving paths or antennas of the plurality of UEs. 7. The method in claim 1 further comprising applying one or more downlink power constraint filters to downlink signals from the BS to the UEs in equalizing the G matrix to satisfy power constraints in the downlink signals. 8. The method in claim 1 further comprising applying one or more uplink power constraint filters to uplink signals from the UEs to the BS in equalizing the G matrix to satisfy power constraints in the uplink signals. 9. The method in claim 1 further comprising estimating the channel matrix G in the frequency-domain and equalizing the channel between the BS and the channel emulator by applying a compensation matrix in the frequency-domain to equalize the effect of the G matrix such that the channel emulator effectively emulates specified channel models between the M transmitting or receiving paths or antennas of the BS and K≥2 transmitting or receiving paths or antennas of the plurality of UEs. 10. The method in claim 1 further comprising using a radio frequency (RF) chamber and RF configuration to produce a large coherence bandwidth and long coherence time of the channel between the BS and the channel emulator. 11. The method in claim 1 further comprising generating pilot patterns that multiplex the pilot signals for estimating the channel between the BS and the channel emulator through Time-Division Multiplexing (TDM), Frequency-Division Multiplexing (FDM), Code-Division Multiplexing (CDM), or a combination of them. 12. The method in claim 11 further comprising each transmitting path or antenna transmits at least two pilots with the same time index but different frequency indices to compensate an offset. 13. The method in claim 11 further comprising each transmitting path or antenna transmits at least two pilots with the same frequency index but different time indices to compensate an offset. 14. The method in claim 1 wherein a specific time and frequency resource is assigned to each transmitting path or antenna to make the pilot signal transmitted from each transmitting path or antenna separable from the pilot signals transmitted from other transmitting paths or antennas. 15. The method in claim 14 further comprising a receiver using the assigned time and frequency resource of a pilot signal transmitted by each transmitting path or antenna to separate it out from the pilot signals transmitted by other transmitting paths or antennas. 16. The method in claim 14 further comprising assigning two frequency resources to each transmitting path or antenna at a symbol time slot in the time domain for offset correction in estimating the channel between the BS and the channel emulator. 17. The method in claim 14 further comprising assigning an identical frequency resource to each transmitting path or antenna at two symbol time slots in the time domain for offset correction in estimating the channel between the BS and the channel emulator. 18. A method for testing a multi-user multiple input multiple output (MU-MIMO) wireless communication system comprising: creating an over-the-air (OTA) connection between antennas of a base station (BS) with M>2 transmitting or receiving paths or antennas and a channel emulator with N>2 transmitting or receiving paths or antennas; transmitting pilot signals between the M transmitting paths or antennas of the BS and the channel emulator for estimating an N×M channel matrix G between the BS and the channel emulator wherein the pilot signal transmitted from each transmitting path or antenna of the BS is made to be separable from the pilot signals transmitted from the other transmitting paths or antennas of the BS; receiving the pilot signals, processing the received pilot signals to separate out the pilot signal transmitted by each transmitting path or antenna, and using the pilot signals to estimate the channel matrix G r