Abstract: Disclosed is a fault tolerant CMOS image sensor that includes circuitry for identifying defective pixels and masking them during image generation. Masking may involve, in one example, replacing the output of a given pixel with an average of the output of surrounding non-faulty pixels. Thus, while image sensors may be fabricated with some number of faulty pixels, the images produced by such sensors will not have undesirable bright or dark spots. The disclosed sensor includes (a) one or more pixels (active or passive) capable of providing outputs indicative of a quantity of radiation to which each of the one or more pixels has been exposed; and (b) one or more circuit elements electrically coupled to the one or more pixels and configured to identify and correct faulty pixels in the CMOS imager. The one more pixels each include a photodiode diffusion formed in a well and a tap to power or ground also formed in the well.

Abstract: Disclosed is a fault tolerant CMOS image sensor that includes circuitry for identifying defective pixels and masking them during image generation. Masking may involve, in one example, replacing the output of a given pixel with an average of the output of surrounding non-faulty pixels. Thus, while image sensors may be fabricated with some number of faulty pixels, the images produced by such sensors will not have undesirable bright or dark spots. The disclosed sensor includes (a) one or more pixels (active or passive) capable of providing outputs indicative of a quantity of radiation to which each of the one or more pixels has been exposed; and (b) one or more circuit elements electrically coupled to the one or more pixels and configured to identify and correct faulty pixels in the CMOS imager. The one more pixels each include a photodiode diffusion formed in a well and a tap to power or ground also formed in the well.

Abstract: Disclosed is a fault tolerant CMOS image sensor that includes circuitry for identifying defective pixels and masking them during image generation. Masking may involve, in one example, replacing the output of a given pixel with an average of the output of surrounding non-faulty pixels. Thus, while image sensors may be fabricated with some number of faulty pixels, the images produced by such sensors will not have undesirable bright or dark spots. The disclosed sensor includes (a) one or more pixels (active or passive) capable of providing outputs indicative of a quantity of radiation to which each of the one or more pixels has been exposed; and (b) one or more circuit elements electrically coupled to the one or more pixels and configured to identify and correct faulty pixels in the CMOS imager. The one more pixels each include a photodiode diffusion formed in a well and a tap to power or ground also formed in the well.

Abstract: Disclosed is a CMOS image sensor that includes circuitry for identifying defective pixels, particularly pixels having leaky access switches. The leaky access switches allow charge to escape from the pixel over a row or column line in a pixel array, thereby corrupting the outputs of an entire row or column of pixels. A disclosed test involves (a) electronically setting a defined charge in a selected pixel of the CMOS imager; (b) reading the output of the selected pixel; and (c) comparing the output of the selected pixel to an expected value based upon the defined charge set in the selected pixels. If the output significantly deviates from the expected value, then the selected pixel is identified as having a leaky access switch. Preferably, a newly fabricated sensor is first tested as described. If such leaky access switch is discovered, the imager is discarded without incurring further manufacturing cost.

Abstract: Disclosed is a CMOS image sensor that includes circuitry for identifying defective pixels, particularly pixels having leaky access switches. The leaky access switches allow charge to escape from the pixel over a row or column line in a pixel array, thereby corrupting the outputs of an entire row or column of pixels. A disclosed test involves (a) electronically setting a defined charge in a selected pixel of the CMOS imager; (b) reading the output of the selected pixel; and (c) comparing the output of the selected pixel to an expected value based upon the defined charge set in the selected pixels. If the output significantly deviates from the expected value, then the selected pixel is identified as having a leaky access switch. Preferably, a newly fabricated sensor is first tested as described. If such leaky access switch is discovered, the imager is discarded without incurring further manufacturing cost.

Abstract: A method of and system for providing user input to a computer captures a first finger position image at a first time and a second finger position image at a second time. The first and second finger position images each comprise a plurality of numerical gray scale values equal to or greater than zero. The system then subtracts the first finger position image from the second finger position image to obtain a composite image. The composite image has a first region comprising numerical values less than zero and a second region comprising numerical values greater than zero. The system provides X-Y input to the computer based upon the relative positions of first and second regions. The system further provides Z input to the computer based upon the relative sizes of said first and second regions.

Abstract: A low-cost semiconductor user input device for controlling the position of a pointer on a display includes a small array of composite sensors. Each composite sensor of the array is adapted to detect movement of a fingerprint feature. The user input device moves the pointer based upon the net movement detected by the composite sensors of the array.

Abstract: Disclosed is a method and associated apparatus for compensating for kTC noise in individual pixels of an MOS imaging array. The kTC noise at issue forms when a pixel is disconnected from a reset voltage by turning off an MOS transistor which controls access to the pixel photodiode. Compensation is accomplished by first exposing the photodiode to the reset voltage and then disconnecting the well region from V.sub.dd to cause it to float. By allowing the well to float, the kTC charge subsequently introduced (at the conclusion of the reset process) redistributes so that most of it accumulates on the capacitor between the well and the substrate. Later, the well is reclamped to V.sub.dd, and the noise contribution stored in the well-substrate capacitor is canceled. A disclosed apparatus includes an array of pixels, each having a separate well. In addition, access of the well to a source of power (V.sub.dd) must be switchable. Therefore, a transistor is included at each pixel's connection to a V.sub.dd.