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Low-voltage 96 dB snapshot CMOS image sensor with 4.5 nW power dissipation per pixel.

Spivak A, Teman A, Belenky A, Yadid-Pecht O, Fish A - Sensors (Basel) (2012)

Bottom Line: This sensor features several power reduction techniques, including a dual voltage supply, a selective power down, transistors with different threshold voltages, a non-rationed logic, and a low voltage static memory.The proposed power-saving solutions have allowed the maintenance of the standard architecture of the sensor, reducing both the time and the cost of the design.An SNR of 48 dB and DR of 96 dB were achieved with a power dissipation of 4.5 nW per pixel.

View Article: PubMed Central - PubMed

Affiliation: The VLSI Systems Center, LPCAS, Ben-Gurion University, P.O.B. 653, Be'er-Sheva 84105, Israel. spivakar@bgu.ac.il

ABSTRACT
Modern "smart" CMOS sensors have penetrated into various applications, such as surveillance systems, bio-medical applications, digital cameras, cellular phones and many others. Reducing the power of these sensors continuously challenges designers. In this paper, a low power global shutter CMOS image sensor with Wide Dynamic Range (WDR) ability is presented. This sensor features several power reduction techniques, including a dual voltage supply, a selective power down, transistors with different threshold voltages, a non-rationed logic, and a low voltage static memory. A combination of all these approaches has enabled the design of the low voltage "smart" image sensor, which is capable of reaching a remarkable dynamic range, while consuming very low power. The proposed power-saving solutions have allowed the maintenance of the standard architecture of the sensor, reducing both the time and the cost of the design. In order to maintain the image quality, a relation between the sensor performance and power has been analyzed and a mathematical model, describing the sensor Signal to Noise Ratio (SNR) and Dynamic Range (DR) as a function of the power supplies, is proposed. The described sensor was implemented in a 0.18 um CMOS process and successfully tested in the laboratory. An SNR of 48 dB and DR of 96 dB were achieved with a power dissipation of 4.5 nW per pixel.

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Block diagram of the sensor.
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f1-sensors-12-10067: Block diagram of the sensor.

Mentions: The sensor architecture is divided in accordance with the dual supply approach into two separate power domains: analog and digital. Each one of the power domains is biased by a separate power supply AVDD and DVDD, respectively (Figure 1). The darker areas are included in the analog power domain, which is biased with higher supply voltage, AVDD. The bright areas are included within the digital domain, powered by the lower supply voltage, DVDD. In this section we will discuss the design of blocks according to the power domain in which a certain block is found.


Low-voltage 96 dB snapshot CMOS image sensor with 4.5 nW power dissipation per pixel.

Spivak A, Teman A, Belenky A, Yadid-Pecht O, Fish A - Sensors (Basel) (2012)

Block diagram of the sensor.
© Copyright Policy
Related In: Results  -  Collection

License
Show All Figures
getmorefigures.php?uid=PMC3472816&req=5

f1-sensors-12-10067: Block diagram of the sensor.
Mentions: The sensor architecture is divided in accordance with the dual supply approach into two separate power domains: analog and digital. Each one of the power domains is biased by a separate power supply AVDD and DVDD, respectively (Figure 1). The darker areas are included in the analog power domain, which is biased with higher supply voltage, AVDD. The bright areas are included within the digital domain, powered by the lower supply voltage, DVDD. In this section we will discuss the design of blocks according to the power domain in which a certain block is found.

Bottom Line: This sensor features several power reduction techniques, including a dual voltage supply, a selective power down, transistors with different threshold voltages, a non-rationed logic, and a low voltage static memory.The proposed power-saving solutions have allowed the maintenance of the standard architecture of the sensor, reducing both the time and the cost of the design.An SNR of 48 dB and DR of 96 dB were achieved with a power dissipation of 4.5 nW per pixel.

View Article: PubMed Central - PubMed

Affiliation: The VLSI Systems Center, LPCAS, Ben-Gurion University, P.O.B. 653, Be'er-Sheva 84105, Israel. spivakar@bgu.ac.il

ABSTRACT
Modern "smart" CMOS sensors have penetrated into various applications, such as surveillance systems, bio-medical applications, digital cameras, cellular phones and many others. Reducing the power of these sensors continuously challenges designers. In this paper, a low power global shutter CMOS image sensor with Wide Dynamic Range (WDR) ability is presented. This sensor features several power reduction techniques, including a dual voltage supply, a selective power down, transistors with different threshold voltages, a non-rationed logic, and a low voltage static memory. A combination of all these approaches has enabled the design of the low voltage "smart" image sensor, which is capable of reaching a remarkable dynamic range, while consuming very low power. The proposed power-saving solutions have allowed the maintenance of the standard architecture of the sensor, reducing both the time and the cost of the design. In order to maintain the image quality, a relation between the sensor performance and power has been analyzed and a mathematical model, describing the sensor Signal to Noise Ratio (SNR) and Dynamic Range (DR) as a function of the power supplies, is proposed. The described sensor was implemented in a 0.18 um CMOS process and successfully tested in the laboratory. An SNR of 48 dB and DR of 96 dB were achieved with a power dissipation of 4.5 nW per pixel.

Show MeSH
Related in: MedlinePlus