2021
DOI: 10.3390/electronics10091096
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A Low Dark Current 160 dB Logarithmic Pixel with Low Voltage Photodiode Biasing

Abstract: Extending CMOS Image Sensors’ dynamic range is of fundamental importance in applications, such as automotive, scientific, or X-ray, where a broad variation of incoming light should be measured. The typical logarithmic pixels suffer from poor performance under low light conditions due to a leakage current, usually referred to as the dark current. In this paper, we propose a logarithmic pixel design capable of reducing the dark current through low-voltage photodiode biasing, without introducing any process modif… Show more

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Cited by 5 publications
(5 citation statements)
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“…Additionally, for lowlight imaging applications, a linear-logarithmic counter in a high-dynamic-range image sensor enables user-programmable sensitivity modification [32]. Furthermore, a logarithmic pixel design, achieved by utilizing a low-voltage photodiode bias to reduce dark current, enhances dynamic range and dark responsiveness [33]. In intelligent sensor networks, employing the maximum logarithm message transmission technique preserves precision and efficiency, while simultaneously reducing the complexity of multinode detection.…”
Section: Discussionmentioning
confidence: 99%
“…Additionally, for lowlight imaging applications, a linear-logarithmic counter in a high-dynamic-range image sensor enables user-programmable sensitivity modification [32]. Furthermore, a logarithmic pixel design, achieved by utilizing a low-voltage photodiode bias to reduce dark current, enhances dynamic range and dark responsiveness [33]. In intelligent sensor networks, employing the maximum logarithm message transmission technique preserves precision and efficiency, while simultaneously reducing the complexity of multinode detection.…”
Section: Discussionmentioning
confidence: 99%
“…Figure 11b illustrates the second type of pixel, i.e., the active pixel sensor (APS) [65,[81][82][83][84][85][86][87], which consists of a matrix of pixels in the same way as the PPS, but with the difference of containing three MOSFETs, where M 1 is the reset transistor, M 2 is the amplifying transistor, and M 3 is the pixel address transistor. The APS has three modes of operation: the reset mode, the integration mode, and the readout mode [12,22,35,[88][89][90]. The reset signal closes the reset transistor M 1 during the first mode and directly connects the N-type region of the photodetector to the supply voltage V dd .…”
Section: Architectures 41 Photocurrent Integrationmentioning
confidence: 99%
“…To better display the image, many commercial photography devices have a non-linear response to light intensity [ 2 ]. Non-linearity is intentionally implemented for purposes like high-dynamic-range image sensors [ 3 , 4 ], or to match human visual perception [ 5 ]. But for accurate measurements, like in some medical and scientific imaging fields, optical sensors require precise light intensity and frequency responses [ 6 ], where the linearity of the sensor becomes an important parameter.…”
Section: Introductionmentioning
confidence: 99%