Acoustic metamaterial

What is claimed is: 1. A metamaterial, comprising: a plurality of flow sensors, each configured to sense a three dimensional vector flow state of a primary fluid wave in a medium and produce an electrical sensor signal in response; a transducer, configured to emit a secondary fluid wave within the medium in response to an output, having a three dimensional vector flow state selectively dependent on the sensed three dimensional vector flow state of the primary fluid wave; and an automated control, configured to: receive the electrical sensor signal from each of the plurality of flow sensors; perform a time and space transform on the electrical sensor signal from each of the plurality of flow sensors with an automated transform processor to determine a three dimensional spatial flow pattern of the primary fluid wave and a scattering of the primary fluid wave by an element; and produce the output in accordance with a result of the time and space transform, to emit the secondary fluid wave which interferes with at least the scattering of the primary fluid wave. 2. The metamaterial according to claim 1 , wherein the transducer comprises a phased array transducer having an emission pattern which does not direct the secondary fluid wave toward the plurality of fluid vector flow sensors. 3. The metamaterial according to claim 1 , wherein the transducer has an emission pattern which emits the secondary fluid wave which is sensed by at least one of plurality of vector flow sensors. 4. The metamaterial according to claim 1 , wherein the time and space transform approximates a metamaterial transfer function. 5. The metamaterial according to claim 1 , wherein each respective flow sensor comprises at least one sensing fiber which is displaceable by viscous drag by wave movement of the medium and has a sensing fiber movement which corresponds to a wave movement of air over a range of at least 1-100 Hz. 6. The metamaterial according to claim 5 , wherein each respective flow sensor comprises a set of three orthogonal sensing fibers. 7. The metamaterial according to claim 1 , wherein the element comprises a core, and transducer is controlled to counteract an effect of the core on the primary fluid wave. 8. The metamaterial according to claim 1 , wherein: the plurality of fluid vector flow sensors surround the element; and the transducer comprises a transducer array configured to respond to a control signal to negate the interference of propagation of the primary fluid wave across the element. 9. The metamaterial according to claim 1 , wherein each fluid flow sensor comprises a conductive fiber suspended in a magnetic field, configured to produce an electromagnetically induced voltage corresponding to a movement of the medium corresponding to the primary fluid wave. 10. A metamaterial method, comprising: sensing a three dimensional vector flow state of a primary fluid wave in a medium with a plurality of flow sensors, each flow sensor producing an electrical sensor signal responsive to a flow state of the primary fluid wave; performing a time and space transform on the electrical sensor signal from each of the plurality of flow sensors with an automated transform processor to determine a three dimensional spatial flow pattern of the primary fluid wave and a scattering of the primary fluid wave by an element; and emitting a secondary fluid wave within the medium having a three dimensional vector flow state selectively dependent on the time and space transform, which interferes with at least the scattering of the primary fluid wave. 11. The metamaterial method according to claim 10 , wherein the transducer comprises a phased array transducer having an emission pattern which does not direct the secondary fluid wave toward the plurality of fluid vector flow sensors. 12. The metamaterial method according to claim 10 , wherein the transducer comprises a phased array transducer having an emission pattern which emits the secondary fluid wave which is sensed by at least one of plurality of vector flow sensors. 13. The metamaterial method according to claim 10 , wherein the time and space transform approximates a metamaterial transfer function. 14. The metamaterial method according to claim 10 , wherein the medium comprises air, and each respective flow sensor comprises at least one sensing fiber which is displaceable by viscous drag by wave movement of the medium and has a sensing fiber movement which corresponds to a wave movement over a range of at least 1-100 Hz. 15. The metamaterial method according to claim 10 , wherein the medium comprises air, and each respective flow sensor comprises at least one sensing fiber which is displaceable by viscous drag by wave movement of the medium and has a sensing fiber movement which corresponds to a wave movement over a range of at least 10 Hz to 10 kHz. 16. The metamaterial method according to claim 10 , wherein each respective flow sensor comprises at least one sensing fiber which is displaceable by viscous drag by wave movement of the medium, and each respective flow sensor comprises a set of three orthogonal sensing fibers. 17. The metamaterial method according to claim 10 , further comprising controlling the transducer to counteract an effect of the core on the primary fluid wave. 18. The metamaterial method according to claim 10 , wherein: the plurality of fluid vector flow sensors surround the element; and the transducer comprises a phased array transducer configured to respond to a control signal to negate the interference of propagation of the primary fluid wave across the element. 19. The metamaterial method according to claim 10 , wherein each fluid flow sensor comprises a conductive fiber suspended in a magnetic field, further comprising producing an electromagnetically induced voltage corresponding to a movement of the conductive fiber in the magnetic field due to waves in the medium corresponding to the primary fluid wave. 20. A metamaterial, comprising: a flow sensor array, configured to sense a three dimensional vector flow state of a primary fluid wave in a medium and produce an electrical sensor signal in response; a scattering element configured to interact with the primary fluid wave in the medium; a transducer array responsive to a drive signal, configured to emit a secondary fluid wave within the medium having a three dimensional vector flow state selectively dependent on the sensed three dimensional vector flow state of the primary fluid wave to interfere with scattering by the scattering element; and an automated transform processor, configured to perform a time and space transform on the electrical sensor signal, to determine a three dimensional spatial flow pattern of the primary fluid wave and a scattering of the primary fluid wave by the scattering element, and produce the drive signal based on the time and space transform. 21. The metamaterial according to claim 20 , wherein the time and space transform approximates a metamaterial transfer function.