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US-12618816-B2 - Gas concentration sensor and sensor calibration without use of a target gas

US12618816B2US 12618816 B2US12618816 B2US 12618816B2US-12618816-B2

Abstract

A sensor calibration system includes a gas sensor configured to measure a thermal conductivity of a target gas. The gas sensor includes a reference chamber containing a reference gas, a measurement chamber containing a measurement gas, and a calibration circuit. The reference gas has a first thermal conductivity profile and the measurement gas has a, different, second thermal conductivity profile that are dependent on a first environmental stimulus and a second environmental stimulus. The calibration circuit is configured to, while the first environmental stimulus is varied and the second environmental stimulus is fixed, acquire a plurality of measurements. Each measurement of the plurality of measurements is representative of a difference in thermal conductivity between thermal conductivities of the reference gas and the measurement gas. The calibration circuit is configured to determine a target gas sensitivity of the gas sensor to the target gas based on the plurality of measurements.

Inventors

  • Christoph Steiner
  • Matthias Eberl
  • Johannes Hufnagl

Assignees

  • INFINEON TECHNOLOGIES AG

Dates

Publication Date
20260505
Application Date
20230905

Claims (17)

  1. 1 . A sensor calibration system, comprising: a first gas concentration sensor configured to measure a thermal conductivity of a target gas, wherein the first gas concentration sensor comprises: a housing comprising a reference chamber containing a reference gas and a measurement chamber containing a measurement gas, wherein the reference gas has a first thermal conductivity profile and the measurement gas has a second thermal conductivity profile that is different from the first thermal conductivity profile, wherein the first thermal conductivity profile and the second thermal conductivity profile are dependent on a first environmental stimulus and a second environmental stimulus, wherein the reference chamber is a closed chamber containing the reference gas and the measurement chamber is an open chamber exposed to the measurement gas; and a calibration circuit configured to acquire a first plurality of measurements, wherein the calibration circuit is configured to acquire the first plurality of measurements while the first environmental stimulus of the reference chamber and the measurement chamber is varied and while the second environmental stimulus of the reference chamber and the measurement chamber is fixed, wherein each measurement of the first plurality of measurements is representative of a difference in thermal conductivity between a thermal conductivity of the reference gas and a thermal conductivity of the measurement gas, wherein each measurement of the first plurality of measurements corresponds to a different value of the first environmental stimulus, and wherein the calibration circuit is configured to determine a first thermal conductivity sensitivity of the first gas concentration sensor based on the first plurality of measurements.
  2. 2 . The sensor calibration system of claim 1 , wherein the first environmental stimulus is temperature and the second environmental stimulus is pressure, wherein the first environmental stimulus is pressure and the second environmental stimulus is temperature, or wherein the first environmental stimulus is humidity and the second environmental stimulus is temperature.
  3. 3 . The sensor calibration system of claim 1 , wherein the target gas, the reference gas, and the measurement gas are different gases.
  4. 4 . The sensor calibration system of claim 3 , wherein the target gas is helium gas or hydrogen gas, the reference gas is oxygen gas, nitrogen gas, or air, and the measurement gas is oxygen gas, nitrogen gas, or air.
  5. 5 . The sensor calibration system of claim 1 , wherein the thermal conductivity of the reference gas depends on the first environmental stimulus, the second environmental stimulus, and the first thermal conductivity profile, and the thermal conductivity of the measurement gas depends on the first environmental stimulus, the second environmental stimulus, and the second thermal conductivity profile.
  6. 6 . The sensor calibration system of claim 1 , wherein the calibration circuit is configured to determine the first thermal conductivity sensitivity of the first gas concentration sensor based on an estimated slope of the first plurality of measurements.
  7. 7 . The sensor calibration system of claim 6 , wherein the first thermal conductivity sensitivity is equal to the estimated slope of the first plurality of measurements.
  8. 8 . The sensor calibration system of claim 1 , wherein, while the measurement chamber is exposed to the target gas and a concentration of the target gas in the measurement chamber is varied, the calibration circuit is configured to acquire a second plurality of measurements, wherein each measurement of the second plurality of measurements corresponds to a different concentration of the target gas, and wherein the calibration circuit is configured to determine a first target gas sensitivity of the first gas concentration sensor to the target gas based on the second plurality of measurements.
  9. 9 . The sensor calibration system of claim 8 , wherein the first environmental stimulus of the reference chamber and the measurement chamber is fixed and the second environmental stimulus of the reference chamber and the measurement chamber is fixed while the calibration circuit acquires the second plurality of measurements.
  10. 10 . The sensor calibration system of claim 8 , wherein the calibration circuit is configured to determine the first target gas sensitivity based on an estimated slope of the second plurality of measurements.
  11. 11 . The sensor calibration system of claim 8 , wherein the calibration circuit is configured to calibrate the first gas concentration sensor for performing a measurement of the target gas based on the first target gas sensitivity.
  12. 12 . The sensor calibration system of claim 8 , wherein the first gas concentration sensor is configured to compensate for a measurement of the target gas based on the first target gas sensitivity to generate a compensated measurement of the target gas.
  13. 13 . The sensor calibration system of claim 8 , wherein the calibration circuit is configured to calculate a correction factor based on the first thermal conductivity sensitivity and the first target gas sensitivity, wherein the calibration circuit is configured to determine a second thermal conductivity sensitivity of a second gas concentration sensor, wherein the calibration circuit is configured to calculate a second target gas sensitivity of the second gas concentration sensor based on the second thermal conductivity sensitivity and the correction factor, and wherein the calibration circuit is configured to calibrate the second gas concentration sensor for performing a measurement of the target gas based on the second target gas sensitivity.
  14. 14 . The sensor calibration system of claim 1 , wherein the first gas concentration sensor comprises: a first reference piezoresistive wire arranged in the reference chamber and exposed to the reference gas, wherein the first reference piezoresistive wire has a first resistance value based on the thermal conductivity of the reference gas; and a first measurement piezoresistive wire arranged in the measurement chamber, and exposed to the measurement gas, and connected to the first reference piezoresistive wire in a first half-bridge, wherein the first measurement piezoresistive wire has a second resistance value based on the thermal conductivity of the measurement gas, wherein, while a voltage is applied across the first half-bridge, the calibration circuit is configured to acquire the first plurality of measurements by sampling an output of the first half-bridge.
  15. 15 . The sensor calibration system of claim 14 , wherein the first gas concentration sensor comprises: a second reference piezoresistive wire arranged in the reference chamber and exposed to the reference gas, wherein the second reference piezoresistive wire has a third resistance value based on the thermal conductivity of the reference gas; and a second measurement piezoresistive wire arranged in the measurement chamber, and exposed to the measurement gas, and connected to the second reference piezoresistive wire in a second half-bridge, wherein the second measurement piezoresistive wire has a fourth resistance value based on the thermal conductivity of the measurement gas, wherein the first half-bridge and the second half-bridge form a full bridge, and wherein, while the voltage is applied across the full bridge, the calibration circuit is configured to acquire the first plurality of measurements by sampling a differential output of the full bridge.
  16. 16 . A sensor calibration system, comprising: a gas concentration sensor configured to measure a thermal conductivity of a target gas, wherein the gas concentration sensor comprises: a housing comprising a reference chamber containing a reference gas and a measurement chamber containing a measurement gas, wherein the reference gas has a first thermal conductivity profile and the measurement gas has a second thermal conductivity profile that is different from the first thermal conductivity profile, wherein the first thermal conductivity profile and the second thermal conductivity profile are dependent on a first environmental stimulus and a second environmental stimulus, wherein the reference chamber is a closed chamber and the measurement chamber is an open chamber exposed to the measurement gas; and a calibration circuit configured to acquire a first plurality of measurements while the first environmental stimulus of the reference chamber and the measurement chamber is varied and while the second environmental stimulus of the reference chamber and the measurement chamber is fixed, wherein each measurement of the first plurality of measurements is representative of a difference in thermal conductivity between a thermal conductivity of the reference gas and a thermal conductivity of the measurement gas, wherein each measurement of the first plurality of measurements corresponds to a different value of the first environmental stimulus, and wherein the calibration circuit is configured to determine a target gas sensitivity of the gas concentration sensor to the target gas based on the first plurality of measurements.
  17. 17 . The sensor calibration system of claim 16 , wherein the gas concentration sensor is configured to compensate for a measurement of the target gas based on the target gas sensitivity to generate a compensated measurement of the target gas.

Description

BACKGROUND There is an increasing demand for reducing the consumption of petroleum and shifting to using green energy. For example, hydrogen generated by wind turbines is considered as a possible green fuel for automotive applications. Sensors may be required to detect any leaking hydrogen to avoid the formation of oxyhydrogen. Sensors for measuring a gas property, which may also be called gas sensors, may have a cross-sensitivity to different environment characteristics, such as humidity, temperature, and/or flow and concentration of the gas to be sensed. In some cases, dedicated sensors for these additional properties may have to be included in order to differentiate the signal of interest. For example, a complementary temperature sensor may have to be added. This may lead to a complex device, where different dies or sensing elements have to be combined inside a package. SUMMARY In some implementations, a sensor calibration system includes a first gas concentration sensor configured to measure a thermal conductivity of a target gas, wherein the first gas concentration sensor comprises: a housing comprising a reference chamber containing a reference gas and a measurement chamber containing a measurement gas, wherein the reference gas has a first thermal conductivity profile and the measurement gas has a second thermal conductivity profile that is different from the first thermal conductivity profile, wherein the first thermal conductivity profile and the second thermal conductivity profile are dependent on a first environmental stimulus and a second environmental stimulus, wherein the reference chamber is a closed chamber containing the reference gas and the measurement chamber is an open chamber exposed to the measurement gas; and a calibration circuit configured to acquire a first plurality of measurements, wherein the calibration circuit acquires the first plurality of measurements while the first environmental stimulus of the reference chamber and the measurement chamber is varied and while the second environmental stimulus of the reference chamber and the measurement chamber is fixed, wherein each measurement of the first plurality of measurements is representative of a difference in thermal conductivity between a thermal conductivity of the reference gas and a thermal conductivity of the measurement gas, wherein each measurement of the first plurality of measurements corresponds to a different value of the first environmental stimulus, and wherein the calibration circuit is configured to determine a first thermal conductivity sensitivity of the first gas concentration sensor based on the first plurality of measurements. In some implementations, a sensor calibration system includes a gas concentration sensor configured to measure a thermal conductivity of a target gas, wherein the gas concentration sensor comprises: a housing comprising a reference chamber containing a reference gas and a measurement chamber containing a measurement gas, wherein the reference gas has a first thermal conductivity profile and the measurement gas has a second thermal conductivity profile that is different from the first thermal conductivity profile, wherein the first thermal conductivity profile and the second thermal conductivity profile are dependent on a first environmental stimulus and a second environmental stimulus, wherein the reference chamber is a closed chamber and the measurement chamber is an open chamber exposed to the measurement gas; and a calibration circuit configured to acquire a first plurality of measurements while the first environmental stimulus of the reference chamber and the measurement chamber is varied and while the second environmental stimulus of the reference chamber and the measurement chamber is fixed, wherein each measurement of the first plurality of measurements is representative of a difference in thermal conductivity between a thermal conductivity of the reference gas and a thermal conductivity of the measurement gas, wherein each measurement of the first plurality of measurements corresponds to a different value of the first environmental stimulus, and wherein the calibration circuit is configured to determine a target gas sensitivity of the gas concentration sensor to the target gas based on the first plurality of measurements. In some implementations, a sensor calibration system includes a first gas concentration sensor configured to measure a thermal conductivity of a target gas, wherein the first gas concentration sensor comprises a first housing comprising a first measurement chamber; a second gas concentration sensor configured to measure the thermal conductivity of the target gas, wherein the second gas concentration sensor comprises a second housing comprising a second measurement chamber; and a calibration circuit configured to, while the first measurement chamber contains a measurement gas, acquire a first plurality of measurements from the first gas concentration sensor an