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Analog Sensor Interface for Field Mill Sensors in Atmospheric Applications.

Zoi Agorastou1, Thomas Noulis1, Stylianos Siskos1

  • 1Electronics Laboratory, Physics Department, Aristotle University of Thessaloniki, 54124 Thessaloniki, Greece.

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Summary
This summary is machine-generated.

This study presents a low-power electric field mill sensor for measuring atmospheric electric fields in various weather conditions. The developed sensor offers cost-effective realization and adequate sensitivity, enabling energy-autonomous operation.

Keywords:
atmospheric applicationselectric field mill sensor interfaceelectric field sensinglow power consumptionnoise optimizedshutter-type field millsystem-on-chip

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Area of Science:

  • Electrical Engineering
  • Atmospheric Science
  • Sensor Technology

Background:

  • Accurate measurement of the atmospheric electric field is crucial for understanding weather phenomena.
  • Existing electric field mill sensors often face challenges with power consumption and complexity.
  • The need for robust and efficient sensors for both fair and foul weather conditions is evident.

Purpose of the Study:

  • To provide an overview of electric field mill sensor specifications for atmospheric electric field measurements.
  • To present and analyze different design approaches for field mill sensor interfaces.
  • To design, implement, and validate a low-power, cost-effective electric field mill sensor.

Main Methods:

  • Overview and analysis of various field mill sensor interface designs.
  • Design and experimental validation of a non-complex analog sensor interface using discrete components.
  • Optimization of an integrated version focusing on noise and power consumption using 180 nm CMOS process simulations.
  • Implementation of an intermittent motor operation for energy-autonomous functionality.

Main Results:

  • A non-complex analog sensor interface was designed and validated.
  • Advanced noise simulations were performed in a 180 nm CMOS process.
  • The sensor achieved low power consumption (165 μW at 3 V) and energy-autonomous operation.
  • The sensing system demonstrated adequate sensitivity (45 mV/kV/m) with a simple and cost-effective realization.

Conclusions:

  • The developed electric field mill sensor is suitable for measuring atmospheric electric fields in fair and foul weather.
  • The sensor's low power consumption and cost-effectiveness make it a viable alternative to existing systems.
  • The design facilitates energy-autonomous operation for extended periods, enhancing its practical applicability.