Abstract: MQW devices, IC chips and methods may be used in semiconductor lithography patterning systems. An MQW device includes an array of pixels that have transmission elements and associated support circuits. The support circuits have preliminary memory cells and final memory cells. The final memory cells store transmittance values that control transmittances of the associated transmission elements. This way, exposure of a target with a lithography system for purposes of patterning the target may be performed through the transmission elements according to the controlled transmittances, while subsequent transmittance values are being received by the preliminary memory cells from memory banks. The exposure of the target therefore needs to pause for less time, in order to wait for the MQW device to be refreshed with the subsequent transmittance values. Accordingly the whole semiconductor lithography patterning system may operate faster and thus have more throughput.

Abstract: Provided are an imaging device implementing pseudo correlated double sampling (CDS), and an imaging method and a control method of the image device. The imaging device includes: a pixel array comprising a pixel configured to generate a current in response to incident light; a readout circuit configured to read out a plurality of output signals of the pixel, the plurality of output signals corresponding to a plurality of consecutive integration periods of the pixel within an aggregating period; and an aggregator configured to aggregate the plurality of output signals read out by the readout circuit to obtain a final aggregated output corresponding to illuminance for the aggregating period, wherein the readout circuit is configured to read out the plurality of output signals by, for each output signal, sampling a signal voltage of the pixel and sampling a subsequent reset voltage of the pixel and obtaining a difference therebetween.

Abstract: MQW devices, IC chips and methods may be used in semiconductor lithography patterning systems. An MQW device includes an array of pixels that have transmission elements and associated support circuits. The support circuits have preliminary memory cells and final memory cells. The final memory cells store transmittance values that control transmittances of the associated transmission elements. This way, exposure of a target with a lithography system for purposes of patterning the target may be performed through the transmission elements according to the controlled transmittances, while subsequent transmittance values are being received by the preliminary memory cells from memory banks. The exposure of the target therefore needs to pause for less time, in order to wait for the MQW device to be refreshed with the subsequent transmittance values. Accordingly the whole semiconductor lithography patterning system may operate faster and thus have more throughput.

Abstract: In some embodiments, an imaging device includes a pixel array. At least one of the pixels includes a photodiode that can generate charges, and a select transistor that receives the charges in its bulk. When the select transistor is selected, a pixel current through it may depend on a number of the received charges, thus evidencing how much light it detected. A reset transistor may reset the voltage of the bulk.

Abstract: An image sensor includes a first array of pixels exhibiting a first sensitivity; a second array of pixels exhibiting a second sensitivity; wherein, the first array of pixels is electrically separated from the second array of pixels. Methods of use and devices using the image sensor are disclosed.

Abstract: MQW devices, IC chips and methods may be used in semiconductor lithography patterning systems. An MQW device includes an array of pixels that have transmission elements and associated support circuits. The support circuits have preliminary memory cells and final memory cells. The final memory cells store transmittance values that control transmittances of the associated transmission elements. This way, exposure of a target with a lithography system for purposes of patterning the target may be performed through the transmission elements according to the controlled transmittances, while subsequent transmittance values are being received by the preliminary memory cells from memory banks. The exposure of the target therefore needs to pause for less time, in order to wait for the MQW device to be refreshed with the subsequent transmittance values. Accordingly the whole semiconductor lithography patterning system may operate faster and thus have more throughput.

Abstract: An embodiment includes a system, comprising a first memory; a plurality of first circuits, wherein each first circuit is coupled to the memory; and includes a second circuit configured to generate a first output value in response to an input value received from the first memory; and an accumulator configured to receive the first output value and generate a second output value; and a controller coupled to the memory and the first circuits, and configured to determine the input values to be transmitted from the memory to the first circuits.

Abstract: A Dynamic Vision Sensor (DVS) where pixel pitch is reduced to increase spatial resolution. The DVS includes shared pixels that employ Time Division Multiplexing (TDM) for higher spatial resolution and better linear separation of pixel data. The pixel array in the DVS may consist of multiple N×N pixel clusters. The N×N pixels in each cluster share the same differentiator and the same comparator using TDM. The pixel pitch is reduced (and, hence, the spatial resolution is improved) by implementing multiple adjacent photodiodes/photoreceptors that share the same differentiator and comparator units using TDM. In the DVS, only one quarter of the whole pixel array may be in use at the same time. A global reset may be done periodically to switch from one quarter of pixels to the other for detection. Because of higher spatial resolution, applications such as gesture recognition or user recognition based on DVS output entail improved performance.

Abstract: A client device configured with a neural network includes a processor, a memory, a user interface, a communications interface, a power supply and an input device, wherein the memory includes a trained neural network received from a server system that has trained and configured the neural network for the client device. A server system and a method of training a neural network are disclosed.

Abstract: Imaging systems, such as time-of-flight imaging systems, and methods with pixel sensitivity adjustments. An embodiment includes a method, comprising: for a plurality of pixels having a first output and a second output, measuring the first outputs and the second outputs in response to a demodulation signal; and adjusting the demodulation signal such that a combination of the first outputs is substantially similar to a combination of the second outputs.

Abstract: Imaging systems, such as time-of-flight imaging systems, and methods with pixel sensitivity adjustments. An embodiment includes a method, comprising: for a plurality of pixels having a first output and a second output, measuring the first outputs and the second outputs in response to a demodulation signal; and adjusting the demodulation signal such that a combination of the first outputs is substantially similar to a combination of the second outputs.

Abstract: Imaging devices and methods detect ambient light level using array pixels. In one embodiment, an imaging device includes an array of imaging pixels that are configured to acquire an image, and an array of dark pixels. A controller may cause at least one of the imaging pixels and of the dark pixels to image concurrently. A monitoring circuit may measure a difference between currents drawn by the imaging pixel and the dark pixel during the concurrent imaging. An indication of ambient light level can be generated according to the difference. The indication can be used as desired, for example to manage the brightness of the display screen. As such, no separate sensors are required, apart from the imaging array that is already provided for imaging.

Abstract: Provided are an imaging device implementing pseudo correlated double sampling (CDS), and an imaging method and a control method of the image device. The imaging device includes: a pixel array comprising a pixel configured to generate a current in response to incident light; a readout circuit configured to read out a plurality of output signals of the pixel, the plurality of output signals corresponding to a plurality of consecutive integration periods of the pixel within an aggregating period; and an aggregator configured to aggregate the plurality of output signals read out by the readout circuit to obtain a final aggregated output corresponding to illuminance for the aggregating period, wherein the readout circuit is configured to read out the plurality of output signals by, for each output signal, sampling a signal voltage of the pixel and sampling a subsequent reset voltage of the pixel and obtaining a difference therebetween.

Abstract: A pixel array includes regular pixels for imaging, and special pixel sites interspersed among the regular pixels. When the regular pixels become saturated from bright illumination, at least some of their excess charges are removed by the special pixel sites. The removal can reduce or eliminate blooming. In some embodiments, the special pixel sites include special pixels. For imaging, the regular pixels of a group such as a sub-array provide regular outputs that are combined into a composite signal. The special pixels provide a special output. The special output of the group may optionally be added to the composite signal, which can increase the dynamic range.

Abstract: An imaging device has a pixel array that includes one or more depth pixels. The imaging device also includes a controller that can cause one or more of the depth pixels to image a depth of an object in a ranging mode. The controller can further cause the depth pixel(s) to image in one or more detection modes, with the appropriate control signals. The imaging device also includes a monitoring circuit that can detect a current drawn by the depth pixel(s) in the detection modes. A revert indication can be generated from the detected current. Depending on the control signals, the revert indication can serve as a proximity indication, or as a motion indication.

Abstract: A pixel array includes color pixels that have a layout, and depth pixels having a layout that starts from the layout of the color pixels. Photodiodes of adjacent depth pixels can be joined to form larger depth pixels, while still efficiently exploiting the layout of the color pixels. Moreover, some embodiments are constructed so as to enable freeze-frame shutter operation of the pixel array.

Abstract: An imaging device has an array with pixels that can image an aspect of an object. In addition, pixels in the array can be used to perform motion detection or edge detection. A first and a second pixel can integrate light non-concurrently, and then their outputs may be compared. A difference in their outputs may indicate an edge in an imaging operation, and motion in a motion detection operation. The motion detection operation may be performed without needing the imaging device to have an additional modulated LED light source, and to spend the power to drive that source.