Abstract: A method of sub sampling signals from an image sensor having a pixel array. The pixel array has a plurality of columns, each column having a column readout circuit. The method comprises averaging the signals output by a plurality of adjacent column readout circuits and outputting the averaged signal to an output bus.

Abstract: The image sensor includes a first group and a second group of column readout circuits for reading out pixel signals from said pixels. The total number of column readout circuits in each group is substantially less than the number of columns in the image sensor pixel array. Further included is a multiplexer bus system having selection switches for selectively switching pixel signals from a block of pixels in a column as input into the first group of column readout circuits. The multiplexer bus system also selectively switches pixel signals from another block of pixels in a column as input into a second group of column readout circuits. However, when the first group of column readout circuits is reading and storing said pixel signals, the second group of column readout circuits is transferring out the processed signals. Thus, the first and second groups work alternately.

Abstract: An improved active pixel sensor soft reset circuit for reducing image lag while maintaining low reset kTC noise. The circuit pulls down the sensor potential to a sufficiently low level before the soft reset function is completed. The level to which the sensor potential is pulled is set between 0 and the critical potential at which the reset transistor will be on when the soft reset function begins. The timing of the pull down function is such that the sensor is stabilized at the low potential before the soft reset function completes. In one embodiment, the sensor potential is pulled down using a pull-down circuit, which may consist of a CMOS type inverter. In another embodiment, the sensor potential is pulled down by the bit line. Two ways in which the bit line may be pulled down are natural discharge, or by increasing the bias on the loading transistor. Two ways in which the bias on the loading transistor may be increased are a biasing circuit, or by using a pull-down transistor.

Abstract: An improved active pixel sensor soft reset circuit for reducing image lag while maintaining low reset kTC noise. The circuit pulls down the sensor potential to a sufficiently low level before the soft reset function is completed. The level to which the sensor potential is pulled is set between 0 and the critical potential at which the reset transistor will be on when the soft reset function begins. The timing of the pull down function is such that the sensor is stabilized at the low potential before the soft reset function completes. In one embodiment, the sensor potential is pulled down using a pull-down circuit, which may consist of a CMOS type inverter. In another embodiment, the sensor potential is pulled down by the bit line. Two ways in which the bit line may be pulled down are natural discharge, or by increasing the bias on the loading transistor. Two ways in which the bias on the loading transistor may be increased are a biasing circuit, or by using a pull-down transistor.

Abstract: The present invention is directed to an analog delay line for a color CMOS image sensor which is compatible with MOS fabrication technology. The invention allows for the simultaneous reading of pixel signals from two rows of pixels so that combinations of signals from pixels in different rows may be obtained. The delay line includes a set of storage capacitors on which the pixel signals are stored, and a means for writing the signals from the pixels onto the capacitors in sequence. The stored analog pixel signals may then be read out from the delay line at the appropriate time so that they may be combined with pixel signals from adjacent pixels in different rows. In one embodiment, two delay lines are used, so that pixel signals from a current row can be written into one delay line, while the pixel signals from a previous row are being read out from the other delay line. In another embodiment, a single delay line is used in combination with a single pixel delay circuit.

Abstract: The active pixel includes a photodiode, a transfer gate, and a reset transistor. The photodiode is substantially covered with an overlying structure, thus protecting the entire surface of the photodiode from damage. This substantially eliminates potential leakage current sources, which result in dark current. In one embodiment, the photodiode is covered by a FOX region in combination with the transfer gate.

Abstract: The active pixel includes a photodiode, a transfer gate, and a reset transistor. The photodiode is substantially covered with an overlying structure, thus protecting the entire surface of the photodiode from damage. This substantially eliminates potential leakage current sources, which result in dark current. In one embodiment, the photodiode is covered by a FOX region in combination with the transfer gate.

Abstract: A method of reading out a pixel signal from a pixel is disclosed. The method comprises first capturing a first black reference signal from the pixel prior to the pixel starting an integration period. Next, after completion of the integration period, a pixel signal is captured. Next, a second black reference signal is captured following completion of the integration period. Finally, the first black reference signal, second black reference signal, and pixel signal is output.

Abstract: A column readout circuit for a CMOS image sensor is disclosed. The circuit uses MOS capacitors to store a photo signal and a reset signal. Correlated double sampling is used to eliminate fixed pattern noise and 1/f noise. Additionally, the signals are coupled through the capacitors using AC coupling. In this manner, a readout circuit compatible with conventional CMOS logic processes can be manufactured.

Abstract: In a CMOS image sensor, it is important to control the exposure time or gain. For varying changes in ambient light, the exposure time of the array must be changed. The present invention describes a method for controlling the exposure time or gain to ensure a smooth and fast change in the brightness of the obtained image. If the exposure time is the be decremented or incremented, then the gain control is increased or decreased, respectively to smooth out the changes in image brightness. This substantially reduces image flicker.

Abstract: The active pixel includes a photodiode, a transfer gate, and a reset transistor. The photodiode is substantially covered with an overlying structure, thus protecting the entire surface of the photodiode from damage. This substantially eliminates potential leakage current sources, which result in dark current. In one embodiment, the photodiode is covered by a FOX region in combination with the transfer gate.

Abstract: In a CMOS image sensor, it is important to control the exposure time or gain. For varying changes in ambient light, the exposure time of the array must be changed. The present invention describes a method for controlling the exposure time or gain. Each of the intensities of the pixels in a frame is analyzed to provide an indication of the number of pixels having an intensity above or below multiple predetermined thresholds. This information is then used to change the exposure time. The magnitude of change in the exposure time is also determined by the number of pixels having an intensity above or below multiple predetermined thresholds, as the case may be.

Abstract: A method for reducing dark current in a photodiode is disclosed. The photodiode comprises a N-well formed in a P-substrate. The method comprises doping the surface of said N-well with a nitrogen dopant. Alternatively, an oxygen or silicon dopant may be used. Still alternatively, a silicon oxynitride layer may be formed over the N-well.

Abstract: A photodiode with an optimized floating P+ region for a CMOS image sensor. The photodiode is constructed with a P+/Nwell/Psub structure. The Nwell/Psub junction of the photodiode acts as a deep junction photodiode which offers high sensitivity. The P+ floating region passivates the silicon surface to reduce dark currents. Unlike a traditional pinned photodiode structure, the P+ region in the present invention is not connected to the Pwell or Psub regions, thus making the P+ region floating. This avoids the addition of extra capacitance to the cell. The photodiode may be included as part of an active pixel sensor cell, the layout of which is fully compatible with the standard CMOS fabrication process. This type of active pixel sensor cell includes the photodiode, and may be configured with a three transistor configuration for reading out the photodiode signals.

Abstract: The active pixel includes a photodiode, a transfer gate, and a reset transistor. The photodiode is substantially covered with an overlying structure, thus protecting the entire surface of the photodiode from damage. This substantially eliminates potential leakage current sources, which result in dark current. In one embodiment, the photodiode is covered by a FOX region in combination with the transfer gate.

Abstract: The present invention is directed to a method and apparatus for image edge enhancement with background noise reduction. According to the method and apparatus, background noise is reduced through use of feed forward gain control and threshold control of a sharpness control amplifier. In a prior art circuit, the sharpness control amplifier was controlled only by a sharpness control signal. By controlling the sharpness control amplifier also with a feed forward gain control and a threshold control, the circuit can be made to have background noise reduction while maintaining a continuous input/output characteristic curve. According to the input/output characteristic curve, when the amplitude of the transitions of the video signal are below a particular threshold value, the amplification of the sharpness control amplifier is reduced by the gain control, such that low amplitude noise signals are reduced.

Abstract: A photodiode with an optimized floating P+ region for a CMOS image sensor. The photodiode is constructed with a P+/Nwell/Psub structure. The Nwell/Psub junction of the photodiode acts as a deep junction photodiode which offers high sensitivity. The P+ floating region passivates the silicon surface to reduce dark currents. Unlike a traditional pinned photodiode structure, the P+ region in the present invention is not connected to the Pwell or Psub regions, thus making the P+ region floating. This avoids the addition of extra capacitance to the cell. The photodiode may be included as part of an active pixel sensor cell, the layout of which is fully compatible with the standard CMOS fabrication process. This type of active pixel sensor cell includes the photodiode, and may be configured with a three transistor configuration for reading out the photodiode signals.

Abstract: A photodiode with an optimized floating P+ region for a CMOS image sensor. The photodiode is constructed with a P+/Nwell/Psub structure. The Nwell/Psub junction of the photodiode acts as a deep junction photodiode which offers high sensitivity. The P+ floating region passivates the silicon surface to reduce dark currents. Unlike a traditional pinned photodiode structure, the P+ region in the present invention is not connected to the Pwell or Psub regions, thus making the P+ region floating. This avoids the addition of extra capacitance to the cell. The photodiode may be included as part of an active pixel sensor cell, the layout of which is fully compatible with the standard CMOS fabrication process. This type of active pixel sensor cell includes the photodiode, and may be configured with a three transistor configuration for reading out the photodiode signals.

Abstract: The present invention is directed to a single chip color CMOS image sensor with a novel two or more line reading structure which is compatible with MOS fabrication technology. The invention allows the simultaneous reading of line signals from two adjacent rows of pixels so that combinations of signals from pixels in adjacent rows may be obtained without the use of an external delay line device. The sensor includes a pixel array having superimposed thereon a color filter pattern and a two or more line reading structure. The reading structure includes sets of storage capacitors on which the pixel signals are stored, and a means for reading the signals from the capacitors in such a way that signals from pixels in adjacent rows may be combined. The reading structure is external to the pixel array but may still be fabricated on the same CMOS chip as the pixel array.

Abstract: A column amplifier for high fixed pattern noise reduction. The column amplifier includes a switching capacitor amplifier, a sample and hold stage, and an output buffer. The switching capacitor amplifier receives signals from a bit line that is coupled to a column of active pixel sensors. The switching capacitor amplifier is capacitively coupled to the bit line from a column of active pixel sensors and is able to cancel the common mode offset in the bit line. The common mode can also be adjusted in the switching capacitor amplifier, such that the last stage of the column amplifier (e.g., the buffer stage) is not limited by the common mode level of the active pixel sensors. The switching capacitor amplifier includes an input capacitor and a feedback capacitor. The gain of the switching capacitor amplifier amplifies the pixel signals so that the fixed pattern noise introduced by stages after the switching capacitor amplifier will comprise a lower proportion of the total signal.