Image sensing with a display

What is claimed is: 1. An imaging system comprising: a cover glass having a display surface; a pixelated photoemitting element array, one or more selected photoemitting elements of the pixelated photoemitting element array being configured to emit a light signal through the cover glass to the display surface; and a pixelated photodetecting element array positioned relative to the pixelated photoemitting element array and the cover glass to receive a reflected light signal at individual photodetecting elements of the pixelated photodetecting element array, the reflected light signal including a portion of the emitted light signal reflected by total internal reflection from a refractive boundary at the display surface of the cover glass; and wherein the reflected light signal includes a non-feature portion of the emitted light signal resulting from total internal reflection from the refractive boundary at the display surface of the covered glass. 2. The imaging system of claim 1 wherein the reflected light signal excludes a portion of the emitted light signal transmitted through the refractive boundary at the display surface. 3. The imaging system of claim 1 wherein the reflected light signal excludes a portion of the emitted light signal transmitted through the refractive boundary at the display surface, the transmitted portion of the emitted light signal having an angle of incidence with the display surface that is less than a critical angle of the refractive boundary at the display surface of the cover glass. 4. The imaging system of claim 1 wherein the reflected light signal includes a portion of the emitted light signal reflected by total internal reflection, the reflected portion of the emitted light signal having an angle of incidence with the display surface that is greater than a critical angle of the refractive boundary at the display surface of the cover glass. 5. The imaging system of claim 1 wherein the reflected light signal includes a feature-scattered portion of the emitted light signal resulting from total internal reflection from the refractive boundary at the display surface of the cover glass, the feature-scattered portion of the emitted light signal corresponding to a region of optical coupling at the refractive boundary at the display surface of the cover glass and an optically-coupled feature of an object on the display surface of the cover glass. 6. The imaging system of claim 1 , wherein the non-feature portion of the emitted light signal corresponding to a region of the display surface of the cover glass in which a feature of an object is not optically coupled at the refractive boundary at the display surface of the cover glass. 7. The imaging system of claim 1 further comprising: imaging processing circuitry electronically connected to the pixelated photodetecting element array and configured to stitch the reflected light signal received by each photodetecting element of the pixelated photodetecting element array into a composite image of an object in contact with the display surface of the display. 8. The imaging system of claim 1 further comprising: imaging processing circuitry electronically connected to the pixelated photoemitting element array and the pixelated photodetecting element array and configured to scan emitted light from an area of the pixelated photoemitting element array and to capture by the pixelated photodetecting element array the scanned emitted light as the reflected light signal as the scanned emitted light reflects from the refractive boundary at the display surface of the cover glass. 9. The imaging system of claim 1 , wherein the pixelated photoemitting element array includes pixelated elements that are also light-emitting elements of the display surface. 10. The imaging system of claim 1 , wherein the reflected light signal passes through at least a portion of the display surface prior to arriving at the pixelated photodetecting element array. 11. A method comprising: emitting a light signal through a cover glass of a display to a display surface of the display, the light signal being emitted from one or more selected photoemitting elements of a pixelated photoemitting element array of the display; and capturing a reflected light signal at individual photodetecting elements of a pixelated photodetecting element array positioned relative to the pixelated photoemitting element array and the cover glass to receive the reflected light signal, the reflected light signal including a portion of the emitted light signal reflected by total internal reflection from a refractive boundary at the display surface of the cover glass; and wherein the reflected light signal includes a non-feature portion of the emitted light signal resulting from total internal reflection from the refractive boundary at the display surface of the covered glass. 12. The method of claim 11 wherein the reflected light signal excludes a portion of the emitted light signal transmitted through the refractive boundary at the display surface. 13. The method of claim 11 wherein the reflected light signal excludes a portion of the emitted light signal transmitted through the refractive boundary at the display surface, the transmitted portion of the emitted light signal having an angle of incidence with the display surface that is less than a critical angle of the refractive boundary at the display surface of the cover glass. 14. The method of claim 11 wherein the reflected light signal includes a portion of the emitted light signal reflected by total internal reflection, the reflected portion of the emitted light signal having an angle of incidence with the display surface that is greater than a critical angle of the refractive boundary at the display surface of the cover glass. 15. The method of claim 11 wherein the reflected light signal includes a feature-scattered portion of the emitted light signal resulting from total internal reflection from the refractive boundary at the display surface of the covered glass, the feature-scattered portion of the emitted light signal corresponding to a region of optical coupling at the refractive boundary at the display surface of the cover glass and an optically-coupled feature of an object on the display surface of the cover glass. 16. The method of claim 11 wherein, the non-feature portion of the emitted light signal corresponding to a region of the display surface of the cover glass in which a feature of an object is not optically coupled at the refractive boundary at the display surface of the cover glass. 17. The method of claim 11 further comprising: stitching the captured reflected light signal received by each photodetecting element of the photodetecting element array into a composite image of an object in contact with the display surface of the display. 18. The method of claim 11 further comprising: scanning emitted light from an area of the pixelated photoemitting element array and to capture by the pixelated photodetecting element array the scanned emitted light as the reflected light signal as the scanned emitted light reflects from the refractive boundary at the display surface of the cover glass. 19. An electronic device comprising: a cover glass having a display surface; a pixelated photoemitting element array, one or more selected photoemitting elements of the pixelated photoemitting element array being configured to emit a light signal through the cover glass to the display surface; a pixelated photodetecting element array positioned relative to the pixel