Imaging structure emitter configurations

The invention claimed is: 1. An imaging structure, comprising: a silicon backplane with a driver pad array; embedded light sources formed on the driver pad array in an emitter material layer, the embedded light sources configured as direct emitters for individual control at the driver pad array, the emitter material layer including a pyramid or cylindrical structure to improve optical extraction of emitted light; and multiple rows of the embedded light sources configured to generate and emit the light for scanning by an imaging unit to generate a scanned image for display, the multiple rows of the embedded light sources configured in two rows of green embedded light sources, two rows of red embedded light sources, and two rows of blue embedded light sources for increased scanning speed of the imaging unit. 2. An imaging structure as recited in claim 1 , wherein the embedded light sources are formed in inorganic material as one of lasers or LEDs for direct light emission. 3. A method, comprising: forming a silicon backplane with a driver pad array that individually controls embedded light sources; forming the embedded light sources as direct emitters on the driver pad array in an emitter material layer, the emitter material layer including a pyramid or cylindrical structure to improve optical extraction of emitted light; forming a conductive material layer over the embedded light sources; and configuring the embedded light sources in multiple rows to generate and emit light for scanning by an imaging unit to generate a scanned image for display, the embedded light sources configured in a first row of green embedded light sources and a second row of alternating red and blue embedded light sources, the green embedded light sources generating luminance data for the scanned image, and the alternating red and blue embedded light sources generating chroma data for the scanned image. 4. A method as recited in claim 3 , wherein the embedded light sources are formed in inorganic material as one of lasers or LEDs for direct light emission. 5. A wearable display device, comprising: left and right display lens systems configured for augmented reality imaging; left and right imaging units of the respective left and right display lens systems configured to generate an augmented reality image; each of the left and right imaging units including an imaging structure that comprises: a silicon backplane with a driver pad array configured to individually control embedded light sources that are formed as direct emitters on the driver pad array in an emitter material layer, a conductive material layer formed over the embedded light sources with a rough surface effective to allow more light emission out from the emitter material layer rather than be reflected or dispersed; and multiple rows of the embedded light sources configured to generate and emit light for scanning to generate a scanned image for display. 6. A wearable display device as recited in claim 5 , wherein the embedded light sources are formed in inorganic material as one of lasers or LEDs for direct light emission. 7. An imaging structure as recited in claim 1 , wherein each of the embedded light sources are configured to illuminate based on one of current modulation, pulse-width modulation, or specific time and power parameters. 8. An imaging structure as recited in claim 1 , wherein the imaging unit includes a mirror that performs the scanning of the multiple rows of the embedded light sources in one dimension to generate the scanned image for display. 9. An imaging structure as recited in claim 1 , further comprising a conductive material layer formed over the embedded light sources to form a p-n junction between the emitter material layer and the conductive material layer. 10. An imaging structure as recited in claim 1 , wherein the emitter material layer includes a reflective structure to reflect the light to exit the embedded light sources. 11. A method as recited in claim 3 , wherein each of the embedded light sources are configured to illuminate based on one of current modulation, pulse-width modulation, or specific time and power parameters. 12. A method as recited in claim 3 , wherein the imaging unit includes a mirror that performs the scanning of the multiple rows of the embedded light sources in one dimension to generate the scanned image for display. 13. A method as recited in claim 3 , wherein the emitter material layer includes a reflective structure to reflect the light to exit the embedded light sources. 14. A wearable display device as recited in claim 5 , wherein each of the embedded light sources are configured to illuminate based on one of current modulation, pulse-width modulation, or specific time and power parameters. 15. A wearable display device as recited in claim 5 , wherein each of the imaging units include a mirror that performs the scanning of the multiple rows of the embedded light sources in one dimension to generate the scanned image for display. 16. A wearable display device as recited in claim 5 , further comprising the conductive material layer formed over the embedded light sources to form a p-n junction between the emitter material layer and the conductive material layer. 17. A wearable display device as recited in claim 5 , wherein the emitter material layer includes a reflective structure to reflect the light to exit the embedded light sources. 18. A wearable display device as recited in claim 5 , wherein the emitter material layer includes a pyramid or cylindrical structure to improve optical extraction of the emitted light. 19. A method as recited in claim 3 , wherein: the first row of the green embedded light sources have full resolution; and the second row of the alternating red and blue embedded light sources have reduced resolution. 20. An imaging structure as recited in claim 9 , wherein the conductive material layer is formed with a rough surface effective to allow more light emission out from the emitter material layer rather than be reflected or dispersed.