Massively multi-user MIMO using space time holography

What is claimed is: 1. An antenna system, comprising: one or more feeds configured to receive an electromagnetic (EM) signal and propagate the EM signal as an EM reference wave; a plurality of tunable EM scattering elements spaced at sub-wavelength distances, the plurality of tunable EM scattering elements configured to operate in at least two different operational states of a plurality of different operational states to selectively scatter the EM reference wave as a radiated wave; and control circuitry comprising a controller operably coupled to the plurality of tunable EM scattering elements through a plurality of high frequency EM transmission lines, the controller programmed to modulate the plurality of tunable EM scattering elements between the plurality of different operational states over time through a plurality of isolated and decoupled control lines to modulate the radiated wave over time for delivering a plurality of different information streams to a plurality of different far-end locations, wherein the plurality of high frequency EM transmission lines are configured to transmit EM waves having a frequency of at least about twice a frequency of the reference wave. 2. The antenna system of claim 1 , wherein the EM signal is a monochromatic continuous wave EM signal. 3. The antenna system of claim 1 , wherein the plurality of high-frequency EM transmission lines includes a plurality of optical transmission lines, and the plurality of tunable EM scattering elements includes a plurality of optically tunable EM scattering elements tunable by optical signals transmitted through the plurality of optical transmission lines. 4. The antenna system of claim 3 , wherein the plurality of optical transmission lines includes a plurality of optical fibers. 5. The antenna system of claim 3 , wherein the controller is programmed to modulate the plurality of optically tunable EM scattering elements at a frequency of at least about one (1) gigahertz. 6. The antenna system of claim 3 , wherein the controller is programmed to modulate the plurality of optically tunable EM scattering elements at a time scale that is longer than a time that it takes for the radiated wave to travel from the plurality of optically tunable EM scattering elements to the plurality of different far-end locations. 7. The antenna system of claim 6 , wherein the controller is programmed to modulate the plurality of optically tunable EM scattering elements as a temporal series of modulation patterns, wherein each modulation pattern of the series is determined by solving a time invariant holographic projection manifold function. 8. The antenna system of claim 7 , wherein the controller is programmed to solve the time invariant holographic projection manifold functions using a Green's function. 9. The antenna system of claim 3 , wherein the controller is programmed to modulate the plurality of optically tunable EM scattering elements at a time scale that is shorter than a time that it takes for the radiated wave to travel from the plurality of optically tunable EM scattering elements to the plurality of different far-end locations. 10. The antenna system of claim 9 , wherein the controller is programmed to modulate the plurality of optically tunable EM scattering elements as a series of modulation patterns, wherein at least a portion of the modulation patterns of the series is determined by solving a time variant holographic projection manifold function. 11. The antenna system of claim 10 , wherein the controller is programmed to solve the time variant holographic projection manifold function using a retarded Green's function. 12. The antenna system of claim 3 , wherein the two or more different operational states comprises more than two operational states. 13. The antenna system of claim 12 , wherein the controller is programmed to transition the antenna system between different holograms gradually. 14. The antenna system of claim 13 , wherein the controller is programmed to transition between the different holograms by smoothing control signals delivered to the plurality of optically tunable EM scattering elements with smoothed Heaviside functions. 15. The antenna system of claim 13 , wherein the controller is programmed to transition between the different holograms by smoothing control signals delivered to the plurality of optically tunable EM scattering elements with piecewise-trigonometric functions. 16. The antenna system of claim 3 , wherein the controller is programmed to modulate the radiated wave over time to deliver a plurality of different frequency modulated information streams to the plurality of different far-end locations. 17. The antenna system of claim 1 , further comprising a plurality of acoustic transmission lines operably coupling the controller to the plurality of tunable EM scattering elements, and wherein the plurality of tunable EM scattering elements includes a plurality of acoustically tunable EM scattering elements tunable by acoustic signals transmitted through the plurality of acoustic transmission lines. 18. A method of operating an antenna system, the method comprising: receiving and propagating an electromagnetic (EM) signal as an EM reference wave; operating a plurality of tunable EM scattering elements spaced at sub-wavelength distances in at least two different operational states of a plurality of different operational states to selectively scatter the EM reference wave as a radiated wave; and modulating the plurality of tunable EM scattering elements between the plurality of different operational states over time through a plurality of isolated and decoupled control lines to modulate the radiated wave over time to deliver a plurality of different information streams to a plurality of different far-end locations, wherein the plurality of tunable EM scattering elements are controlled using a plurality of high frequency EM transmission lines configured to transmit EM waves having a frequency of at least about twice a frequency of the reference wave. 19. The method of claim 18 , wherein receiving and propagating an EM signal comprises receiving and propagating a monochromatic continuous wave EM signal. 20. The method of claim 18 , wherein receiving and propagating an EM signal comprises receiving and propagating a modulated EM signal. 21. The method of claim 18 , wherein controlling the tunable EM scattering elements using a plurality of high frequency EM transmission lines includes controlling the tunable EM scattering elements using a plurality of optical transmission lines, and wherein the plurality of tunable EM scattering elements includes a plurality of optically tunable EM scattering elements tunable by optical signals transmitted through the plurality of optical transmission lines. 22. The method of claim 18 , wherein controlling the tunable EM scattering elements with control lines includes controlling the tunable EM scattering elements using a plurality of acoustic transmission lines, and wherein the plurality of tunable EM scattering elements includes a plurality of acoustically tunable EM scattering elements tunable by acoustic signals transmitted through the plurality of acoustic transmission lines. 23. The method of claim 22 , wherein controlling the plurality of acoustically tunable EM scattering elements comprises modulating the plurality of acoustically tunable EM scattering elements at a frequency of at least about one (1) gigahertz. 24.