A current mirror is a fundamental circuit configuration used in electronic circuits to replicate or copy the current from one transistor to another. It is a common building block in integrated circuits and finds various applications in analog and mixed-signal designs. The concept of current mirrors is based on the principle that the current flowing through a diode-connected transistor (a transistor biased in the saturation or active region with its gate and drain connected) is proportional to the current flowing through its source.
The most basic form of a current mirror consists of two transistors: a reference transistor (diode-connected) and a mirror transistor (connected in the same diode configuration). The reference transistor is biased with a known current, typically through a current source, and the mirror transistor attempts to copy this current. Ideally, the mirror transistor's current should be equal to the reference current, making it a faithful "mirror" of the original current.
Applications of current mirrors in electronic circuits include:
Biasing circuits: Current mirrors are commonly used in biasing circuits to provide a stable and precise bias current for other transistors in the circuit. By mirroring a reference current, the biasing circuit can ensure consistent operating conditions for multiple transistors.
Differential amplifier: Current mirrors are employed in differential amplifier configurations to improve input impedance and provide better matching between transistors, leading to improved common-mode rejection and enhanced performance.
Current sources/sinks: Current mirrors can be used to generate accurate and stable current sources or sinks, which are essential in various circuit designs like voltage regulators and current-mode amplifiers.
Output stages: Current mirrors are used in the output stages of operational amplifiers, as they can increase output current capability and improve linearity.
Voltage references: Current mirrors are part of voltage reference circuits used to generate precise voltage levels, which are crucial in many analog and mixed-signal applications.
Current scaling: Current mirrors are used to scale currents in electronic circuits, allowing designers to control current ratios and tailor the behavior of specific circuit blocks.
It is important to note that real-world current mirrors may have limitations due to transistor mismatch, temperature variations, and process-related imperfections. Designers often use techniques such as cascoding and compensation to mitigate these issues and achieve higher accuracy and reliability in practical applications.