Thermometer-adapter
A simple operational amplifier and silicon diode form the core of a temperature-to-voltage converter, which allows the use of a standard voltmeter—either analog or digital—to measure temperature. User adjustments enable readings of either 10 mV or 100 mV to correspond to 1 °F or °C. The temperature sensor D1 is a 1N4148 silicon diode with a temperature coefficient of -2 mV/°C. The op amp U1, a 741 model, is configured as a differential amplifier. A voltage divider composed of resistor R3 and Zener diode D2 generates a 6.2 V reference voltage. D2 is paired with potentiometer R4, allowing for offset adjustments to align the output voltage with either the Celsius or Fahrenheit scale, depending on preference. Gain control resistor R2 is set to ensure that the op amp's output is within the voltage range suitable for the meter in use. After setting R2, R4 is adjusted so that the output voltage accurately represents degrees Celsius or Fahrenheit. The thermometer adapter can be calibrated by modifying R4 while the probe sensor is exposed to a known temperature.
The temperature-to-voltage converter circuit utilizes an operational amplifier (op amp) configured in a differential amplifier arrangement to process the voltage signal generated by the temperature sensor. The 1N4148 silicon diode serves as the temperature sensor, producing a negative voltage change of 2 mV for every degree Celsius increase in temperature. This characteristic allows for temperature measurement through voltage output.
The op amp U1, a standard 741 model, amplifies the signal from the diode. The gain control resistor R2 is critical in setting the amplification level to ensure that the output voltage is appropriate for the specific voltmeter being used. Careful selection of R2 allows the circuit to accommodate a variety of voltmeter sensitivities.
The voltage divider formed by resistor R3 and Zener diode D2 provides a stable reference voltage of 6.2 V. This reference is essential for accurate differential measurements. The inclusion of potentiometer R4 enables fine-tuning of the output voltage, allowing users to adjust the offset so that the output can be calibrated to either the Celsius or Fahrenheit scale. This flexibility is important for applications where specific temperature scales are required.
Calibration of the thermometer adapter is achieved by adjusting R4 while the diode sensor is placed in a controlled temperature environment. This ensures that the output voltage corresponds accurately to the known temperature, thereby validating the performance of the temperature-to-voltage converter circuit. The combination of these components creates a versatile and accurate method for temperature measurement using standard voltmeters, suitable for various applications in electronics and instrumentation.A simple op amp and silicon diode are the heart of the temperature-to-voltage converter that will permit you to use an ordinary voltmeter-either analog or digital-to measure temperature. User adjustments make it possible for a reading of either 10 mV or 100 mV to represent 1 °F or C. Temperature sensor D1 is a 1N4148 silicon diode. It has a temperature coefficient of -2 mV/°C. Ul, a 741 op amp, is connected as a differential amplifier. A voltage divider consisting of R3 and Zener diode D2 provides a 6.2 V reference voltage. D2 is shunted by potentiometer R4, so that the offset can be adjusted to align the output voltage with either the Celsius or Falrrenheit scale, as desired.
Gain control R2 is adjusted so the output of the op amp is in the scale or voltage range of the meter being used. R4, the offset adjust control, is then adjusted so the output voltage represents either degrees For C.
The thermometer adapter can be calibrated by adjusting R4 while the probe sensor is at a known temperature.
The temperature-to-voltage converter circuit utilizes an operational amplifier (op amp) configured in a differential amplifier arrangement to process the voltage signal generated by the temperature sensor. The 1N4148 silicon diode serves as the temperature sensor, producing a negative voltage change of 2 mV for every degree Celsius increase in temperature. This characteristic allows for temperature measurement through voltage output.
The op amp U1, a standard 741 model, amplifies the signal from the diode. The gain control resistor R2 is critical in setting the amplification level to ensure that the output voltage is appropriate for the specific voltmeter being used. Careful selection of R2 allows the circuit to accommodate a variety of voltmeter sensitivities.
The voltage divider formed by resistor R3 and Zener diode D2 provides a stable reference voltage of 6.2 V. This reference is essential for accurate differential measurements. The inclusion of potentiometer R4 enables fine-tuning of the output voltage, allowing users to adjust the offset so that the output can be calibrated to either the Celsius or Fahrenheit scale. This flexibility is important for applications where specific temperature scales are required.
Calibration of the thermometer adapter is achieved by adjusting R4 while the diode sensor is placed in a controlled temperature environment. This ensures that the output voltage corresponds accurately to the known temperature, thereby validating the performance of the temperature-to-voltage converter circuit. The combination of these components creates a versatile and accurate method for temperature measurement using standard voltmeters, suitable for various applications in electronics and instrumentation.A simple op amp and silicon diode are the heart of the temperature-to-voltage converter that will permit you to use an ordinary voltmeter-either analog or digital-to measure temperature. User adjustments make it possible for a reading of either 10 mV or 100 mV to represent 1 °F or C. Temperature sensor D1 is a 1N4148 silicon diode. It has a temperature coefficient of -2 mV/°C. Ul, a 741 op amp, is connected as a differential amplifier. A voltage divider consisting of R3 and Zener diode D2 provides a 6.2 V reference voltage. D2 is shunted by potentiometer R4, so that the offset can be adjusted to align the output voltage with either the Celsius or Falrrenheit scale, as desired.
Gain control R2 is adjusted so the output of the op amp is in the scale or voltage range of the meter being used. R4, the offset adjust control, is then adjusted so the output voltage represents either degrees For C.
The thermometer adapter can be calibrated by adjusting R4 while the probe sensor is at a known temperature.