Creating a simple temperature sensor using a diode (1N4148) and an operational amplifier (741 IC) is straightforward. Here's a step-by-step guide to building this temperature sensor circuit:
Components Needed:- C_Small Unpolarized capacitor, small symbol C1, C2 C_0402_1005Metric
- 1N4148 100V 0.15A standard switching diode, DO-35 D1 D_DO-35_SOD27_P7.62mm_Horizontal
- D_Zener Zener diode D2 D_0402_1005Metric
- Screw_Terminal_01x02 Generic screw terminal, single row, 01x02, script generated (kicad-library-utils/schlib/autogen/connector/) J1, J2 TE_282834-2
- 15K Resistor, small US symbol R1 R_0402_1005Metric
- 1R5 Resistor, small US symbol R2 R_0402_1005Metric
- 10K Potentiometer RV1, RV2 Potentiometer_Bourns_3296W_Vertical
- LM741 Operational Amplifier, DIP-8/TO-99-8 U1 SOT-23-8
1N4148 Diode: This diode has a temperature coefficient of about -2 mV/°C. As the temperature increases, the forward voltage drop across the diode decreases.
741 Op-Amp: This will amplify the small voltage changes across the diode to be easily measured and interpreted as temperature changes.
Circuit Diagram:Diode as a Temperature Sensor:
- Connect the anode of the 1N4148 diode to a fixed resistor of 15K.
- Connect the other end of the resistor to the positive supply voltage of 15V.
- Connect the cathode of the diode to the inverting input (-) of the 741 op-amp.
Setting Up the Op-Amp:
- Connect a resistor (e.g., 10kΩ) between the inverting input (-) of the op-amp and the op-amp output.
- Connect a reference voltage to the op-amp's non-inverting input (+). This reference voltage can be set using a voltage divider network from the supply voltage (two resistors in series between the supply voltage and ground, with the midpoint connected to the non-inverting input).
Powering the Op-Amp:
- Connect the positive supply voltage of 15V to the V+ pin of the 741 IC.
- Connect the negative supply voltage of -15V to the V- pin of the 741 IC.
- Ensure that the power supply's ground is connected to the common ground of the circuit.
Output Measurement:
- The output voltage of the op-amp will vary with the temperature. As the temperature increases, the forward voltage drop across the diode decreases, causing a change in the voltage at the inverting input of the op-amp.
- The op-amp amplifies this voltage change, and the output voltage can be measured using a multimeter.
Calibration:
- To calibrate the sensor, measure the output voltage at known temperatures (e.g., ice water at 0°C and boiling water at 100°C).
- Create a calibration curve or equation relating the output voltage to the temperature.
- Use this calibration to interpret the output voltage in terms of temperature.
Example Calculations:
Assume the diode forward voltage drop at 25°C is about 0.7V. If the temperature coefficient is -2 mV/°C, then for every degree Celsius increase in temperature, the forward voltage drop decreases by two mV.
Troubleshooting Tips:
- Ensure all connections are secure and correct.
- Verify the power supply voltages.
- Check the reference voltage set at the non-inverting input.
- Use proper heat sinks and ventilation if the circuit gets too hot.
Following these steps and understanding the basic principles, you can create a simple and effective temperature sensor using a 1N4148 diode and a 741 op-amp.
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