A voltage follower, also known as a buffer amplifier, is a simple electronic circuit that has an input and an output, and its primary purpose is to replicate the input voltage at its output while providing a high input impedance and a low output impedance. In other words, it "follows" the input voltage, maintaining the same voltage level but with the ability to drive more current or lower impedance loads.
The basic configuration of a voltage follower circuit consists of an operational amplifier (op-amp) with a feedback loop where the output is connected back to the inverting input terminal. This configuration ensures that the op-amp's inverting input is virtually at the same potential as the non-inverting input, which causes the output to closely track the input voltage.
Components of a Voltage Follower Circuit:
Operational Amplifier (Op-Amp): The op-amp is the heart of the voltage follower circuit. It has a high input impedance and can amplify the difference in voltage between its inputs to produce an output voltage.
Feedback Resistor Network: A resistor is typically used in the feedback path to establish the desired gain of unity (gain = 1), ensuring that the output voltage follows the input voltage.
Applications of Voltage Follower (Buffer) Circuits:
Impedance Matching: One of the primary applications of a voltage follower is to match the impedance between a source and a load. When a source impedance is high and needs to drive a load with low impedance, a voltage follower can be used to bridge this impedance gap without significantly affecting the voltage level.
Voltage Level Shifting: In cases where you need to shift the voltage level of a signal while maintaining its integrity, a voltage follower can be employed. It can shift a signal from one voltage level to another without introducing loading effects.
Isolation: Voltage followers can be used to isolate the input and output stages of a circuit. This is particularly useful in situations where the load impedance might vary and you want to protect the previous stage from these variations.
Buffering Weak Signals: Weak signals that have high output impedance can lose their integrity when connected to a load. A voltage follower can buffer such signals and prevent signal degradation.
Driving Multiple Loads: Sometimes a single source needs to drive multiple loads, each with different impedance characteristics. A voltage follower can provide a consistent voltage to each load without drawing excessive current from the source.
Minimizing Loading Effects: When you connect a load to a signal source, it can alter the source's characteristics due to the loading effect. A voltage follower placed between the source and the load can minimize these effects by presenting a high input impedance to the source and a low output impedance to the load.
In summary, a voltage follower or buffer circuit is a valuable tool in electronics for maintaining signal integrity, impedance matching, and isolation between different stages of a circuit. It ensures that the output voltage closely follows the input voltage while providing necessary impedance transformations.