In the context of feedback systems, loop gain is a fundamental concept that plays a crucial role in determining the system's stability. It refers to the product of gains around the feedback loop, which includes all the elements involved in the loop, such as amplifiers, filters, and other signal processing components.
In a feedback control system, the output of the system is fed back and compared with the desired reference input to generate an error signal. This error signal is then processed and used to adjust the system's behavior, aiming to minimize the error and achieve the desired output. The loop gain represents the amplification of the error signal as it traverses the feedback loop.
Mathematically, the loop gain, often denoted as L, is the product of all the gains in the loop. If we have a series of gains in the loop, such as G1, G2, G3, and so on, the loop gain L is given by:
L = G1 * G2 * G3 * ...
The concept of loop gain is closely related to the stability of the feedback system. In a stable system, the loop gain must be less than unity (L < 1). If the loop gain exceeds unity (L > 1), the system becomes unstable, and the output can start to oscillate or diverge, leading to erratic behavior.
To ensure stability, the loop gain's magnitude should be less than one at the frequency where the phase shift of the loop becomes 360 degrees (or a multiple of 360 degrees). This frequency is known as the "unity gain frequency" or the "gain crossover frequency." Beyond this frequency, the loop gain should decrease rapidly with increasing frequency to maintain stability.
Engineers and control system designers analyze the loop gain using techniques such as Bode plots, Nyquist plots, and root locus plots to assess the stability of a feedback system. By adjusting the gains and components within the loop, they can tune the loop gain to ensure system stability and achieve desired performance characteristics.