Systems and techniques for communication using multiple-input-multiple-output processing of orbital angular momentum modes

What is claimed is: 1. A system for radio frequency communication comprising: a transmitter having: a first transmit device having a first transmit antenna and a first orbital-angular-momentum (OAM) multiplexer coupled to the first transmit antenna, wherein the first OAM multiplexer is configured to receive a first input signal and a second input signal, to convert the first input signal to a first OAM beam, and to convert the second input signal to a second OAM beam that is orthogonal to the first OAM beam, wherein the first transmit antenna is configured to transmit a first output signal that includes the first OAM beam and the second OAM beam, and a second transmit device having a second transmit antenna and a second OAM multiplexer coupled to the second transmit antenna, wherein the second OAM multiplexer is configured to receive a third input signal and a fourth input signal, to convert the third input signal to a third OAM beam, and to convert the fourth input signal to a fourth OAM beam that is orthogonal to the third OAM beam, wherein the second transmit antenna is configured to transmit a second output signal that includes the third OAM beam and the fourth OAM beam; and a receiver having: a first receive device having a first receive antenna configured to receive the first output signal and a first OAM demultiplexer coupled to the first receive antenna, wherein the first OAM demultiplexer is configured to convert the first output signal to a first received signal corresponding to the first input signal and a second received signal corresponding to the second input signal, a second receive device having a second receive antenna configured to receive the second output signal and a second OAM demultiplexer coupled to the second receive antenna, wherein the second OAM demultiplexer is configured to convert the second output signal to a third received signal corresponding to the third input signal and a fourth received signal corresponding to the fourth input signal, a multiple-input-multiple-output (MIMO) processor coupled to the first receive device and the second receive device and configured to reduce interference between the first received signal, the second received signal, the third received signal, and the fourth received signal, and a demodulator positioned between the MIMO processor and a combination of the first receive device and the second receive device and configured to demodulate the first received signal, the second received signal, the third received signal, and the fourth received signal; wherein: the first input signal, the second input signal, the third input signal, and the fourth input signal are each modulated according to a first modulation frequency that is within a radio frequency band, the demodulator is configured to demodulate the first received signal, the second received signal, the third received signal, and the fourth received signal by a second modulation frequency that is different than the first modulation frequency, and the MIMO processor is further configured to: receive the first received signal, the second received signal, the third received signal, and the fourth received signal from the demodulator, and further demodulate the first received signal, the second received signal, the third received signal, and the fourth received signal from the demodulator by a third frequency that corresponds to a difference between the first modulation frequency and the second modulation frequency such that the further demodulated first received signal, the further demodulated second received signal, the further demodulated third received signal, and the further demodulated fourth received signal have frequencies that correspond to baseband frequencies of the first input signal, the second input signal, the third input signal, and the fourth input signal, respectively. 2. The system of claim 1 wherein: the first OAM multiplexer includes: a first transmit spiral phase plate (SPP) having a thickness that increases along a circumference of the first transmit SPP and a first thickness delta that corresponds to a difference between a minimum thickness of the first transmit SPP and a maximum thickness of the first transmit SPP and configured to convert the first input signal that corresponds to a first Gaussian beam to the first OAM beam, and a second transmit SPP having a thickness that increases along a circumference of the second transmit SPP and a second thickness delta that corresponds to a difference between a minimum thickness of the second transmit SPP and a maximum thickness of the second transmit SPP, and configured to convert the second input signal that corresponds to a second Gaussian beam to the second OAM beam; the second thickness delta is different than the first thickness delta; and the first thickness delta and the second thickness delta are selected such that the first OAM beam is orthogonal to the second OAM beam. 3. The system of claim 2 wherein the first OAM demultiplexer includes a first receive SPP corresponding to the first transmit SPP and configured to convert the first OAM beam in the received first output signal to the first received signal that corresponds to the first Gaussian beam, and a second receive SPP corresponding to the second transmit SPP and configured to convert the second OAM beam in the received first output signal to the second received signal that corresponds to the second Gaussian beam. 4. The system of claim 1 wherein the MIMO processor is configured to further demodulate the first received signal, the second received signal, the third received signal, and the fourth received signal from the demodulator by: converting each of the first received signal, the second received signal, the third received signal, and the fourth received signal to frequency-domain signals; bandpass filtering the frequency-domain signals about the third frequency; shifting the frequency-domain signals by the third frequency; converting each of the frequency-domain signals to time-domain signals; and resampling each of the time-domain first received signal, the time-domain second received signal, the time-domain third received signal, and the time-domain fourth received signal from the demodulator. 5. The system of claim 1 wherein the first transmit antenna and the second transmit antenna are spaced apart by a distance that is sufficiently small that a combination of the first OAM beam and the second OAM beam overlap with a combination of the third OAM beam and the fourth OAM beam at both of the first receive antenna and the second receive antenna. 6. The system of claim 1 wherein the first transmit device includes a first transmit beam splitter positioned between the first OAM multiplexer and the first transmit antenna and configured to combine the first OAM beam and the second OAM beam into the first output signal. 7. The system of claim 1 wherein the MIMO processor is further configured to reduce the interference between the first received signal, the second received signal, the third received signal, and the fourth received signal using an equalizer of the MIMO processor such that an output of the equalizer for each of the first received signal, the second received signal, the third received signal, and the fourth received signal is represented by an equation y j =Σ i=1 4 {right arrow over (w)} ij *{right arrow over (x)} i where y j represents an output of the equalizer, {right arrow over (w)} ij represents a coefficient vector of the equalizer and corresponds to the interference, {right arrow over (x)} i represents a signal vector of a corresponding received signal, and * represents a convolution operation. 8. A method for radio frequency communication comprising: receiving,