Abstract: A wafer-level array camera includes (i) an image sensor wafer including an image sensor array, (ii) a spacer disposed on the image sensor wafer, and (iii) a lens wafer disposed on the spacer, wherein the lens wafer includes a lens array. A method for fabricating a plurality of wafer-level array cameras includes (i) disposing a lens wafer, including a plurality of lens arrays, on an image sensor wafer, including a plurality of image sensor arrays, to form a composite wafer and (ii) dicing the composite wafer to form the plurality of wafer-level array cameras, wherein each of the plurality of wafer-level array cameras includes a respective one of the plurality of lens arrays and a respective one of the plurality of image sensor arrays.

Abstract: An edge detection method includes reading at least a portion of wide-band pixel signals generated by wide-band pixels of an image sensor. The image sensor also includes narrow-band pixels that generate narrow-band pixel signals that remain unread. The method also includes sending the wide-band pixel signals to an image signal processor, forming a partially-filled reference image based on data from the wide-band pixel signals; and applying an edge-forming technique to the partially-filled reference image to produce an edge map. An edge detection system includes a two-dimensional array of pixels having wide-band pixels and narrow-band pixels, an image signal processor for producing an edge map from a partially-filled reference image, and a readout circuit for generating the partially-filled reference image for the image signal processor. The partially-filled reference is based only on at least part of the wide-band pixels.

Abstract: An image sensor apparatus is disclosed. The image sensor apparatus includes an image sensor for generating image data in a pixel array corresponding to an optical image. A processor alters the image data to embed a feature-dependent code associated with a feature of the image data in a feature-dependent location in the pixel array and generate a digital image from the altered image data.

Abstract: An edge detection method includes reading at least a portion of wide-band pixel signals generated by wide-band pixels of an image sensor. The image sensor also includes narrow-band pixels that generate narrow-band pixel signals that remain unread. The method also includes sending the wide-band pixel signals to an image signal processor, forming a partially-filled reference image based on data from the wide-band pixel signals; and applying an edge-forming technique to the partially-filled reference image to produce an edge map. An edge detection system includes a two-dimensional array of pixels having wide-band pixels and narrow-band pixels, an image signal processor for producing an edge map from a partially-filled reference image, and a readout circuit for generating the partially-filled reference image for the image signal processor. The partially-filled reference is based only on at least part of the wide-band pixels.

Abstract: A wafer-level array camera includes (i) an image sensor wafer including an image sensor array, (ii) a spacer disposed on the image sensor wafer, and (iii) a lens wafer disposed on the spacer, wherein the lens wafer includes a lens array. A method for fabricating a plurality of wafer-level array cameras includes (i) disposing a lens wafer, including a plurality of lens arrays, on an image sensor wafer, including a plurality of image sensor arrays, to form a composite wafer and (ii) dicing the composite wafer to form the plurality of wafer-level array cameras, wherein each of the plurality of wafer-level array cameras includes a respective one of the plurality of lens arrays and a respective one of the plurality of image sensor arrays.

Abstract: An endoscope system of one aspect includes a probe including a CMOS image sensor or sensors, and a conductor or conductors for transmitting an image signal outward from the CMOS image sensor or sensors. The system also includes a connector system including one or more integrated circuits and/or connectors, receiving a signal from the CMOS image sensor or sensors and processing that signal. The system also includes a sensor power supply for the CMOS image sensor or sensors, and a remainder power supply for the remainder of the endoscope system. Other endoscope systems, angiographic systems, devices, and methods associated therewith are also disclosed.

Abstract: A wireless device (400) receives a beacon frame. Using the carrier frequency information included in the beacon frame, a frequency offset value between the wireless device (400) and the wireless host (500) is determined. Based on the frequency offset value, a clock drift value between the host clock (504) in the wireless host (500) and the local clock (406) in the wireless device (400) is determined. The wireless device (400) is then powered up in preparation for receiving a subsequent beacon frame based on the clock drift value between the host clock (504) in the wireless host (500) and the local clock (406) in the wireless device (400).

Abstract: An image sensor apparatus is disclosed. The image sensor apparatus includes an image sensor for generating image data in a pixel array corresponding to an optical image. A processor alters the image data to embed a feature-dependent code associated with a feature of the image data in a feature-dependent location in the pixel array and generate a digital image from the altered image data.