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Controlled current coulometry, also known as amperostatic coulometry, is a technique used in electrochemical analysis to measure the quantity of a substance through the controlled passage of current. It involves the application of a constant current to an electrochemical cell containing the analyte of interest. As the current flows through the cell, the analyte undergoes a redox reaction at the electrode surface, resulting in a charge transfer. By monitoring the time required for a certain...
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Biasing metal-semiconductor junctions involves applying a voltage across the junction. Specifically, the metal is connected to a voltage source, while the semiconductor is grounded. This technique is essential for controlling the direction and magnitude of current flow in electronic devices, including diodes, transistors, and photovoltaic cells.
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Method for Simultaneous fMRI/EEG Data Collection during a Focused Attention Suggestion for Differential Thermal Sensation
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Compact Current Reference Circuits with Low Temperature Drift and High Compliance Voltage.

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Summary

This study introduces a novel current divider circuit using selectable gain amplifiers for precise resistive-sensor conditioning. The new design achieves high accuracy and stability, outperforming traditional methods for sensor interface applications.

Keywords:
current dividercurrent referenceresistive-sensorselectable gain amplifier

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Area of Science:

  • Electrical Engineering
  • Instrumentation and Measurement

Background:

  • Accurate current references are crucial for resistive-sensor conditioning.
  • Existing methods using resistors and active components have limitations due to component inaccuracies and non-linearities.

Purpose of the Study:

  • To develop a highly accurate and stable current reference generator for resistive-sensor conditioning.
  • To leverage the characteristics of LT199x amplifiers for precise current division.

Main Methods:

  • Exploiting LT199x selectable gain amplifiers to divide an input current.
  • Utilizing a 100 µA reference IC to generate precise ~1 µA or ~0.1 µA output currents.
  • Modifying circuit connections to adjust output current without extra components.

Main Results:

  • Achieved precise current sourcing of ~1 µA or ~0.1 µA.
  • Demonstrated excellent linearity for resistive sensors (10 kΩ-100 MΩ) with < ±0.1% relative error post-calibration.
  • Reported a low thermal coefficient (< 10 ppm/°C) and high output resistance (~100 GΩ).
  • Circuit architecture simplifies sensor-interface design by separating current and voltage electrodes.

Conclusions:

  • The proposed current divider offers superior performance for resistive-sensor conditioning compared to conventional approaches.
  • The design's flexibility, accuracy, and stability make it suitable for a wide range of sensor applications, including active sensors.