Transistor Constant Current Sources: The Backbone of Precision Electronics In the world of electronics, achieving stability and precision in circuits is paramount. One of the unsung heroes in this regard is the transistor constant current source. Let's delve into this fascinating topic: What is a Constant Current Source? A constant current source is an electronic circuit that supplies a steady current regardless of the load or voltage applied across it. Unlike a resistor, which has a current that varies with voltage, a constant current source maintains a fixed current, making it invaluable for applications requiring predictable performance. How Does a Transistor Act as a Constant Current Source? Transistors, particularly Bipolar Junction Transistors (BJTs), can be configured to act as constant current sources. The most common setup involves: - Basic Configuration: A transistor with its emitter connected to ground through a resistor, base connected to a voltage source through another resistor, and the collector serving as the output. Here, the base-emitter voltage sets up a current through the emitter resistor, which in turn controls the collector current. - Wilson Current Mirror: An advanced setup where one transistor's base current is mirrored to another, offering better current stability and higher output impedance. - Current Mirror with Diode: Here, a diode or another transistor's base-emitter junction is used to set a reference current, which is then mirrored to the output transistor. Why Use Transistor Constant Current Sources? - Stability: They provide a stable current over varying load conditions, essential in precision circuits like op-amps, ADCs, and DACs. - Temperature Compensation: Transistors can be biased to compensate for temperature changes, ensuring consistent current despite environmental variations. - High Output Impedance: This makes them ideal for driving loads where voltage drop needs to be minimized. Practical Considerations: - Beta Variation: Transistor gain (β) can vary with temperature and from one transistor to another, affecting the current. Hence, choosing matched transistors or employing feedback mechanisms can be crucial. - Early Effect: The collector current can vary with the collector-emitter voltage due to the Early effect, impacting current source accuracy. This can be mitigated with design techniques or selecting transistors with low Early voltage. Applications: - Operational Amplifiers: To set bias currents. - Sensor Circuits: For consistent operation across different sensor resistances. - LED Drivers: To ensure consistent LED brightness. - Battery Chargers: For controlled charging currents. Design Tips: - Choose the Right Transistor: Low β variation and low Early voltage are preferable for precision. - Select Proper Resistors: The values should match the desired current and the transistor's characteristics. - Consider Thermal Stability: Implement temperature compensation if necessary. In conclusion, transistor-based constant current sources are a fundamental building block in modern electronics, providing the precision required for high-performance circuits. Whether you're designing audio equipment, precision instruments, or anything in between, understanding and utilizing these sources can elevate your project's reliability and performance.

@ElecNotes Here is how it‘s designed with CircuitShepherd. The plot shows the load current vs. load resistance.

@ElecNotes Current sources seldom are constant current sources, but have all kind of built in compensation. Barrie Gilbert has said that 70% of the work in designing an IC is designing its bias circuit.