System and method for detecting tactile interaction based on surface variations of a tactile interface

What is claimed is: 1. A touch sensitive device comprising: a tactile interface having non-electrically generated physical surface variations forming a spatially changing tactile pattern, wherein moving tactile interaction with the tactile pattern produces a changing energy signature including mechanical or acoustic vibrations caused by the spatially changing tactile pattern; and an electro-mechanical transducer configured to generate an electrical output signal in response to detecting the energy signature that includes mechanical vibrations or acoustic vibrations, an output of the electro-mechanical transducer connectable to a processor configured to produce a control signal based on the electrical output signal of the electro-mechanical transducer. 2. The touch sensitive device of claim 1 , wherein the surface variations are variations in roughness. 3. The touch sensitive device of claim 2 , wherein the roughness varies across the tactile interface. 4. The touch sensitive device of claim 1 , wherein the tactile pattern is characterized by changes in the surface variations. 5. The touch sensitive device of claim 1 , wherein the energy signature includes an increase or decrease in pitch or spectral content of the mechanical or acoustic vibrations. 6. The touch sensitive device of claim 1 , wherein the tactile interface includes first surface variations forming a first tactile pattern and second surface variations forming a second tactile pattern, wherein the first tactile pattern produces a first energy signature in response to tactile interaction in a first direction and the second tactile pattern produces a second energy signature in response to tactile interaction in a second direction, the second direction different than the first direction, and wherein the electro-mechanical transducer is configured to generate a first electrical output signal in response to detecting the first energy signature and to generate a second electrical output signal in response to detecting the second energy signature, the output of the electro-mechanical transducer connectable to the processor configured to produce a first control signal based on the first electrical output signal and to produce a second control signal based on the second electrical output signal. 7. The touch sensitive device claim 6 , wherein the tactile pattern includes an N by M array of discrete elements, where M<N, the first tactile pattern is formed by M elements of the array and the second tactile pattern is formed by N elements of the array. 8. The touch sensitive device of claim 7 , wherein the discrete elements are defined by boundaries between areas of different roughness. 9. The touch sensitive device of claim 7 , wherein the discrete elements are defined by boundaries between areas of different height substantially normal to the array. 10. The touch sensitive device claim 1 , wherein the tactile pattern includes an array of discrete elements formed on the tactile interface, each discrete element has a first edge and a second edge, wherein a first tactile pattern is formed by the first edges of the discrete elements and a second tactile pattern is formed by the second edges of the discrete elements, wherein the first tactile pattern produces a first energy signature in response to tactile interaction in a first direction and the second tactile pattern produces a second energy signature in response to tactile interaction in a second direction, the second direction different than the first direction, and wherein the electro-mechanical transducer is configured to generate a first electrical output signal in response to detecting the first energy signature and to generate a second electrical output signal in response to detecting the second energy signature, the output of the electro-mechanical transducer connectable to the processor configured to produce a first control signal based on the first electrical output signal and to produce a second control signal based on the second electrical output signal. 11. The touch sensitive device claim 10 , wherein the surface including the tactile interface is nonplanar. 12. The touch sensitive device of claim 1 , wherein the tactile interface is integrated with a housing and the electro-mechanical transducer is coupled to the housing. 13. The touch sensitive device of claim 1 in combination with the processor is configured to produce the control signal based on the electrical output signal of the electro-mechanical transducer. 14. The touch sensitive device of claim 1 , wherein the surface including the tactile interface is molded plastic. 15. The touch sensitive device of claim 1 , wherein the surface including the tactile interface is fabricated metal. 16. The touch sensitive device of claim 1 , wherein the touch sensitive device is integrated in a housing of a hearable device including a sound-producing electro-acoustic transducer that emits sound from an ear-contact portion of the hearable device. 17. The touch sensitive device of claim 1 , wherein the touch sensitive device is integrated in a housing or display interface of a portable electronic device. 18. The touch sensitive device of claim 1 , wherein the touch sensitive device is integrated in a durable goods appliance. 19. The touch sensitive device of claim 1 , wherein the touch sensitive device is integrated in an automobile. 20. The touch sensitive device of claim 1 wherein tactile interaction is detected despite variations in speed or force applied during tactile interaction. 21. A controller comprising: a processor; and a non-transitory computer readable medium storing instructions, when executed by the processor, cause the processor to: obtain an electrical output signal indicating an energy signature, the energy signature representative of non-electrically generated physical surface variations of a tactile interface wherein the physical surface variations form a spatially changing tactile pattern, and determine a characteristic of a moving tactile interaction on the tactile interface according to the electrical output signal, wherein the tactile interaction with the tactile pattern produces a changing energy signature including mechanical or acoustic vibrations caused by the spatially changing tactile pattern. 22. The controller of claim 21 , wherein the energy signature indicates a change in spectral components according to a direction of the tactile interaction. 23. The controller of claim 21 , wherein the energy signature includes an increase or decrease in pitch or spectral content of the mechanical or acoustic vibrations. 24. The controller of claim 21 wherein the processor is operative to detect tactile interaction despite variations in speed or force applied during tactile interaction.