Light guide film control for optically tunable metamaterials

What is claimed is: 1. A metamaterial control device for controlling electromagnetic radiation, said device receiving a light emission, said device comprising: a light-guide film (LGF) substrate having an edge surface for receiving the light emission, said LGF substrate being composed of metamaterial and having an extractor on a non-edge surface of the LGF substrate, said extractor scattering the light emission therefrom as scattered light; an electromagnetic cell structure disposed on said LGF substrate around said extractor, said cell structure having first and second characteristics depending on intensity of said scattered light from said extractor; and an optically sensitive component disposed to cover said extractor and provide said scattered light to said cell structure, wherein said cell structure shifts from said first characteristic to said second characteristic in response to receiving said scattered light from said component. 2. The device according to claim 1 , in which said cell structure is a split-ring resonator. 3. The device according to claim 1 , wherein said first characteristic is photocapacitance, and said second characteristic is one of capacitance and resistance. 4. The device according to claim 1 , wherein said extractor corresponds to a protrusion on said LGF substrate. 5. A metamaterial control device for controlling electromagnetic radiation, said device being disposable a light-guide film (LGF), said LGF being capable of receiving a light emission on an edge surface, said device comprising: a substrate disposed on the LGF, being composed of metamaterial and having an interface that corresponds to an extractor on a non-edge surface of the LGF, said extractor scatterings the light emission as scattered light; an electromagnetic cell structure disposed on said substrate around said extractor, said cell structure having first and second characteristics depending on intensity of said scattered light from said extractor; and an optically sensitive component disposed to cover said extractor and provide said scattered light to said cell structure, wherein said cell structure shifts from said first characteristic to said second characteristic in response to receiving said scattered light from said component. 6. The device according to claim 5 , in which said cell structure is a split-ring resonator. 7. The device according to claim 5 , wherein said first characteristic is photocapacitance, and said second characteristic is one of capacitance and resistance. 8. The device according to claim 5 , wherein said extractor corresponds to a protrusion on said LGF. 9. The device according to claim 5 , wherein said LGF comprises a plurality of light-guide films with distinguishable transmission frequencies. 10. A control device for controlling reactance in response to an emitted light, said device comprising: a light-guide film (LGF) having an edge for receiving the emitted light and an extractor on one of obverse and reverse planar surfaces for scattering the emitted light as scattered light; an electromagnetic cell structure disposed on said LGF around said extractor, said cell structure having first and second characteristics depending on intensity of said scattered light from said extractor; and an optically sensitive component disposed to cover said extractor and provide said scattered light to said cell structure, wherein said cell structure shifts from said first characteristic to said second characteristic in response to receiving said scattered light from said component; a junction disposed on a reverse planar surface; and a via conduit disposed through said LGF for electrically connecting said cell structure and said junction. 11. The device according to claim 10 , wherein said cell structure constitutes a metamaterial split-ring resonator. 12. The device according to claim 10 , wherein said first characteristic is photocapacitance, and said second characteristic is one of capacitance, resistance and inductance. 13. The device according to claim 10 , wherein said cell structure constitutes a metamaterial pad that interacts with an electric field more than with a corresponding magnetic field.