System and method for tactile sensing using thin film optical sensing networks

What is claimed is: 1. A thin-film flexible tactile sensor, comprising: a sensing network formed from an array of optical pathways arranged in a flexible material, each of the optical pathways having an input at a first end thereof and an output at a second end thereof; a plurality of light sources, one for each of the optical pathways, each of the plurality of light sources coupled to the input of a respective associated optical pathway, each of the plurality of light sources directing a light signal having a first predetermined frequency and characteristic into the associated optical pathway; a plurality of light detectors, one for each of the optical pathways, each of the plurality of light detectors coupled to the output of a respective associated optical pathway, each of the plurality of light detectors receiving a light signal from the associated optical pathway and generating an output signal corresponding to the magnitude of the received light signal at a second predetermined frequency; and a processor coupled to receive the output signals from each of the plurality of light detectors and configured to determine an amount of pressure applied to the sensing network based on the received signals from the plurality of light detectors; and wherein each of optical pathways causes variations in the magnitude of light transmitted therethrough to the second end when pressure is applied to an optical pathway in a region in the array, and wherein the processor is configured to determine the amount of pressure applied to the region of the array of optical pathways based at least on changes in the output signals from the one or more light detectors coupled to the one or more optical pathways to which a pressure was applied. 2. The thin-film flexible tactile sensor of claim 1 , wherein the processor is further configured to determine a location within the tactile sensor of the amount of pressure applied to the sensing network based on the received signals from the plurality of light detectors. 3. The thin-film flexible tactile sensor of claim 1 , further comprising input optics coupled between each of the plurality of light sources and the input of the associated optical pathway. 4. The thin-film flexible tactile sensor of claim 3 , wherein the input optics comprise at least one of a polarizer, a polarization rotator and a wavelength selector. 5. The thin-film flexible tactile sensor of claim 1 , further comprising output optics coupled between each of the plurality of light detectors and the output of the associated optical pathway. 6. The thin-film flexible tactile sensor of claim 5 , wherein the output optics comprise at least one of a wavelength selector and a polarization selector. 7. The thin-film flexible tactile sensor of claim 1 , wherein pressure is applied to an optical pathway when pressure is applied to a region of the array of optical pathways. 8. The thin-film flexible tactile sensor of claim 1 , wherein the processor is configured to determine the amount of pressure applied to the region of the array of optical pathways based at least on changes in the output signals from the one or more light detectors reflective of a change in magnitude of light at the second predetermined frequency transmitted to the second end of the one or more optical pathways to which a pressure was applied. 9. The thin-film flexible tactile sensor of claim 1 , wherein the second predetermined frequency is twice the first predetermined frequency. 10. The thin-film flexible tactile sensor of claim 1 , wherein the second predetermined frequency corresponds to Raman Stokes Outputs or Raman Anti-Stokes Outputs of the first predetermined frequency. 11. The thin-film flexible tactile sensor of claim 1 , further comprising: a plurality of second light sources, one for each of the optical pathways, each of the plurality of second light sources coupled to the input of a respective associated optical pathway, each of the plurality of second light sources directing a light signal having a third predetermined frequency and characteristic into the associated optical pathway; and wherein the second predetermined frequency is determined based on a function of the first predetermined frequency and the third predetermined frequency. 12. The thin-film flexible tactile sensor of claim 11 , wherein the function corresponds to a sum-frequency function. 13. The thin-film flexible tactile sensor of claim 11 , wherein the function corresponds to a difference-frequency function. 14. The thin-film flexible tactile sensor of claim 11 , wherein the function corresponds to a simulated Raman Scattering function. 15. The thin-film flexible tactile sensor of claim 1 , wherein the optical pathways form a two-dimensional Cartesian grid and wherein the optical pathways are connected at each crossing point within the two-dimensional Cartesian grid. 16. The thin-film flexible tactile sensor of claim 1 , wherein each of the optical pathways is formed within the flexible material. 17. The thin-film flexible tactile sensor of claim 1 , wherein each of the optical pathways is a separate optical fiber positioned within the flexible material. 18. A thin-film flexible tactile sensor, comprising: a sensing network formed from an array of one or more optical pathways arranged in a flexible material, each of the optical pathways having an input at a first end thereof and an output at a second end thereof; one or more light sources, one for each of the optical pathways, each of the one or more light sources coupled to the input of a respective associated optical pathway, each of the one or more light sources directing a light signal having a first predetermined frequency and characteristic into the associated optical pathway; one or more light detectors, one for each of the optical pathways, each of the one or more light detectors coupled to the output of a respective associated optical pathway, each of the one or more light detectors receiving a light signal from the associated optical pathway and generating an output signal corresponding to the magnitude of the received light signal at a second predetermined frequency; a processor coupled to receive the output signals from each of the one or more light detectors and configured to determine an amount of pressure applied to the sensing network based on the received signals from the one or more light detectors; and wherein each of optical pathways causes variations in the magnitude of the light transmitted therethrough to the second end when pressure is applied to an optical pathway in a region in the array, and wherein the processor is configured to determine the amount of pressure applied to the region of the array of optical pathways based at least on changes in the output signals from the one or more light detectors reflective of a change in magnitude of light at the second predetermined frequency transmitted to the second end of the one or more optical pathways to which a pressure was applied. 19. The thin-film flexible tactile sensor of claim 18 , wherein the processor is further configured to determine a location within the tactile sensor of the amount of pressure applied to the sensing network based on the received signals from the one or more light detectors. 20. A method for sensing pressure using a sensing network formed from an array of optical pathways arranged in a flexible material, each of the optical pathways having an input at a first end thereof and an output at a second end thereof, comprising the steps of: dire