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Related Concept Videos

Temperature Measurement Sites01:14

Temperature Measurement Sites

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A thermometer measures body temperature. The common sites for measuring body temperature are the oral cavity, axillary region, temporal artery, and skin surface, such as the forehead, abdomen, and axilla. True core body temperature is assessed in the rectum, tympanic membrane, pulmonary artery, esophagus, and urinary bladder.
Oral: When assessing oral temperature, the thermometer tip should be placed under the tongue in the posterior sublingual pocket. It offers accurate readings and can be...
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Wide Remote-Range and Accurate Wireless LC Temperature-Humidity Sensor Enabled by Efficient Mutual Interference

Wen Lv1, Yongwei Zhang1, Hanyu Luo1

  • 1Key Laboratory of Thin Film and Microfabrication (Ministry of Education), Department of Micro/Nano Electronics, School of Electronic Information and Electrical Engineering, Shanghai Jiao Tong University, Shanghai 200240, P. R. China.

ACS Sensors
|November 25, 2023
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Summary
This summary is machine-generated.

Inductor-capacitor wireless integrated sensors (LCWISs) now offer improved accuracy and a wider sensing range. This research quantifies internal interferences, enabling high-performance flexible LCWIS for health monitoring and human-machine interfaces.

Keywords:
dual-target sensinginductor-capacitor deviceintegrated electronicsmutual interferencewireless sensor

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Area of Science:

  • Sensor Technology
  • Wearable Electronics
  • Biomedical Engineering

Background:

  • Inductor-capacitor wireless integrated sensors (LCWISs) show promise for untethered health monitoring and human-machine interfaces.
  • Internal interference in LCWIS design limits remote sensing range and accuracy.

Purpose of the Study:

  • To reveal and quantify mutual inductance interferences in LCWIS.
  • To develop a quantified target interference model for accurate multitarget measurements.
  • To design a high-performance flexible LCWIS.

Main Methods:

  • Quantified the mutually exclusive effect of mutual inductance interferences.
  • Developed a target interference model based on interference decomposition.
  • Designed and fabricated a cellulose-polyacrylate-cellulose LCWIS (CPC-LCWIS).

Main Results:

  • Achieved a wide remote sensing range comparable to single-target devices with a 4 mm working radius.
  • Reduced LCWIS area by 16% through optimized design.
  • Demonstrated ultrahigh accuracies (∼1.2% RH, ∼0.18 °C) and high sensitivities (0.36 MHz/°C, 0.25 MHz/% RH) with the CPC-LCWIS.
  • Validated the CPC-LCWIS for health monitoring and human-machine interfaces.

Conclusions:

  • Understanding and quantifying internal interferences is crucial for high-performance LCWIS design.
  • The proposed interference model guides the development of ultra-accurate LCWIS.
  • The developed CPC-LCWIS offers superior performance for advanced wearable electronics in health monitoring and human-machine interfaces.