&lt;title&gt;On-chip binary image processing with CMOS image sensors&lt;/title&gt;

Hong, Canaan Sungkuk; Hornsey, Richard

doi:10.1117/12.463419

“…Processing units can be realized at chip level (system-on-chip approach), at column level by dedicating processing elements to one or more columns (typically analog to digital converters), or at pixel-level by integrating a specific unit in each pixel. Historically, most of the researches have dealt with chip-level and column-level (Dickinson et al, 1995, Kemeny et al, 1997, Hong and Hornsey, 2002Yadid-Pecht and Belenky, 2003;Acosta-Serafini et al 2004;Kozlowski et al 2005;Sakakibara et al 2005). Indeed, pixel-job_20190320093335_Ch7.Ginhac.08.10.12.final.text.kh-corrected-by-dg.docx 7 level processing has been generally dismissed for years because pixel sizes are often too large to be of practical use.…”

Section: < Insert Figure 1 Here >mentioning

confidence: 99%

Smart cameras on a chip: Using complementary metal-oxide-semiconductor (CMOS) image sensors to create smart vision chips

Ginhac¹

2020

High Performance Silicon Imaging

0

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In this chapter, we introduce the fundamental concept of smart cameras on a chip or smart vision chips that simultaneously integrate on the same die image capture capability and highly complex image processing. Successive technology scaling has made possible the integration of specific processing elements designed at chip-level, at columnlevel or at pixel-level. To illustrate this continuous evolution, we survey three different categories of vision chips, exploring first the pioneering works on artificial retinas, then describing the most significant computational chips, and finally presenting the most recent image processing chips able to perform complex algorithms at a high frame rate.

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“…Processing units can be realized at chip level (system-on-chip approach), at column level by dedicating processing elements to one or more columns (typically analog to digital converters), or at pixel-level by integrating a specific unit in each pixel. Historically, most of the researches have dealt with chip-level and column-level (Dickinson et al, 1995, Kemeny et al, 1997, Hong and Hornsey, 2002Yadid-Pecht and Belenky, 2003;Acosta-Serafini et al 2004;Kozlowski et al 2005;Sakakibara et al 2005). Indeed, pixel-job_20190320093335_Ch7.…”

Section: < Insert Figure 1 Here >mentioning

confidence: 99%

Smart cameras on a chip: using complementary metal-oxide-semiconductor (CMOS) image sensors to create smart vision chips

Ginhac

¹

2014

High Performance Silicon Imaging

1

0

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In this chapter, we introduce the fundamental concept of smart cameras on a chip or smart vision chips that simultaneously integrate on the same die image capture capability and highly complex image processing. Successive technology scaling has made possible the integration of specific processing elements designed at chip-level, at columnlevel or at pixel-level. To illustrate this continuous evolution, we survey three different categories of vision chips, exploring first the pioneering works on artificial retinas, then describing the most significant computational chips, and finally presenting the most recent image processing chips able to perform complex algorithms at a high frame rate.

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“…The binary image sensor can be implemented using a simple circuit composed of comparator and D-flip-flop. The binary image sensor is interesting because the captured image in a binary form can be processed using fast logical operations [25][26][27]. The binary image sensor is used in a variety of applications, including motion detectors, character recognition, edge detectors, and barcoding.…”

Section: Introductionmentioning

confidence: 99%

High-speed binary CMOS image sensor using a high-responsivity MOSFET-type photodetector

Choi

¹

,

Jo

²

,

Bae

³

et al. 2015

SPIE Proceedings

0

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In this paper, a complementary metal oxide semiconductor (CMOS) binary image sensor based on a gate/body-tied (GBT) MOSFET-type photodetector is proposed. The proposed CMOS binary image sensor was simulated and measured using a standard CMOS 0.18-μm process. The GBT MOSFET-type photodetector is composed of a floating gate (n+-polysilicon) tied to the body (n-well) of the p-type MOSFET. The size of the active pixel sensor (APS) using GBT photodetector is smaller than that of APS using the photodiode. This means that the resolution of the image can be increased. The high-gain GBT photodetector has a higher photosensitivity compared to the p-n junction photodiode that is used in a conventional APS. Because GBT has a high sensitivity, fast operation of the binary processing is possible. A CMOS image sensor with the binary processing can be designed with simple circuits composed of a comparator and a Dflip-flop while a complex analog to digital converter (ADC) is not required. In addition, the binary image sensor has low power consumption and high speed operation with the ability to switch back and forth between a binary mode and an analog mode.

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<title>On-chip binary image processing with CMOS image sensors</title>

Cited by 9 publications

References 12 publications

Smart cameras on a chip: Using complementary metal-oxide-semiconductor (CMOS) image sensors to create smart vision chips

Smart cameras on a chip: Using complementary metal-oxide-semiconductor (CMOS) image sensors to create smart vision chips

Smart cameras on a chip: using complementary metal-oxide-semiconductor (CMOS) image sensors to create smart vision chips

High-speed binary CMOS image sensor using a high-responsivity MOSFET-type photodetector

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