A 0.5V Energy Efficient CMOS Temperature Sensor with 97.64 pJ/Conversion for Portable Applications

In this article, an energy-efficient smart temperature sensor based on CMOS technology for portable applications is proposed. The whole sensor works in a sub-threshold region to achieve lower power consumption. The front-end circuit of the sensor produces a current in proportion to the absolute temp...

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Veröffentlicht in:	IEEE sensors journal 2023-12, p.1-1
Hauptverfasser:	Jayaram, Chilaka, Rao, Patri Sreehari
Format:	Artikel
Sprache:	eng
Schlagworte:	Energy Efficient Frequency conversion frequency-locked loop and switched capacitor Power demand Sensors Sub-threshold Temperature measurement Temperature sensor Temperature sensors Transistors Wireless sensor networks Wireless sensor Node
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creator	Jayaram, Chilaka Rao, Patri Sreehari
description	In this article, an energy-efficient smart temperature sensor based on CMOS technology for portable applications is proposed. The whole sensor works in a sub-threshold region to achieve lower power consumption. The front-end circuit of the sensor produces a current in proportion to the absolute temperature by utilizing the MOS transistors threshold voltage that changes with the temperature. The current generated by the front-end circuit is then converted into a frequency using the frequency-locked loop (FLL) technique. An asynchronous 12-bit counter is exerted to convert that frequency into a digital value by evaluating the temperature variation in frequency. In addition, to attain better accuracy with power consumption in the nW range, the sensor employs a control circuit that replaces a reference clock generator to provide digital calibration. The sensor has designed in a standard CMOS 180 nm process, and the functionality is analyzed using the post-layout simulation results. At a supply voltage of 0.5 V, the proposed sensor achieves a power consumption of 976.4 nW with an area of 0.0204 mm 2 . The proposed work attains an accuracy of +0.88/-0.90 °C with two-point calibration across a temperature ranging from -40 °C to 125 °C and a resolution of 0.22 °C. Moreover, the experimental results exhibit that the proposed design achieves an energy per conversion of 97.64 pJ with a figure of merit (FoM) of 4.73 pJ.K 2 .
doi_str_mv	10.1109/JSEN.2023.3338957
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The whole sensor works in a sub-threshold region to achieve lower power consumption. The front-end circuit of the sensor produces a current in proportion to the absolute temperature by utilizing the MOS transistors threshold voltage that changes with the temperature. The current generated by the front-end circuit is then converted into a frequency using the frequency-locked loop (FLL) technique. An asynchronous 12-bit counter is exerted to convert that frequency into a digital value by evaluating the temperature variation in frequency. In addition, to attain better accuracy with power consumption in the nW range, the sensor employs a control circuit that replaces a reference clock generator to provide digital calibration. The sensor has designed in a standard CMOS 180 nm process, and the functionality is analyzed using the post-layout simulation results. At a supply voltage of 0.5 V, the proposed sensor achieves a power consumption of 976.4 nW with an area of 0.0204 mm 2 . The proposed work attains an accuracy of +0.88/-0.90 °C with two-point calibration across a temperature ranging from -40 °C to 125 °C and a resolution of 0.22 °C. 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The proposed work attains an accuracy of +0.88/-0.90 °C with two-point calibration across a temperature ranging from -40 °C to 125 °C and a resolution of 0.22 °C. 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The whole sensor works in a sub-threshold region to achieve lower power consumption. The front-end circuit of the sensor produces a current in proportion to the absolute temperature by utilizing the MOS transistors threshold voltage that changes with the temperature. The current generated by the front-end circuit is then converted into a frequency using the frequency-locked loop (FLL) technique. An asynchronous 12-bit counter is exerted to convert that frequency into a digital value by evaluating the temperature variation in frequency. In addition, to attain better accuracy with power consumption in the nW range, the sensor employs a control circuit that replaces a reference clock generator to provide digital calibration. The sensor has designed in a standard CMOS 180 nm process, and the functionality is analyzed using the post-layout simulation results. At a supply voltage of 0.5 V, the proposed sensor achieves a power consumption of 976.4 nW with an area of 0.0204 mm 2 . The proposed work attains an accuracy of +0.88/-0.90 °C with two-point calibration across a temperature ranging from -40 °C to 125 °C and a resolution of 0.22 °C. Moreover, the experimental results exhibit that the proposed design achieves an energy per conversion of 97.64 pJ with a figure of merit (FoM) of 4.73 pJ.K 2 .</abstract><pub>IEEE</pub><doi>10.1109/JSEN.2023.3338957</doi></addata></record>
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subjects	Energy Efficient Frequency conversion frequency-locked loop and switched capacitor Power demand Sensors Sub-threshold Temperature measurement Temperature sensor Temperature sensors Transistors Wireless sensor networks Wireless sensor Node
title	A 0.5V Energy Efficient CMOS Temperature Sensor with 97.64 pJ/Conversion for Portable Applications
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