A Schmitt trigger is a type of electronic circuit used in signal conditioning to convert an input signal into a digital output. It is specifically designed to provide hysteresis, which means it has two different threshold levels for signal switching – one for the rising edge and another for the falling edge. This feature makes the Schmitt trigger especially useful in noise rejection and signal stabilization.
Here's how a Schmitt trigger works in signal conditioning:
Threshold levels: A Schmitt trigger has two threshold levels, one higher (VH) and one lower (VL). When the input signal rises above VH, the output of the Schmitt trigger switches to its high state (e.g., logic 1). Conversely, when the input signal falls below VL, the output switches to its low state (e.g., logic 0).
Hysteresis: The key feature of a Schmitt trigger is its hysteresis, which means the VH threshold level is higher than the VL threshold level. This difference between VH and VL prevents the output from toggling rapidly in response to small fluctuations or noise in the input signal.
Noise rejection: When the input signal is close to the switching threshold, a noisy or jittery signal could cause rapid toggling of the output without hysteresis. With hysteresis in place, the input signal must overcome the threshold level and cross a sufficient voltage difference before the output switches, making the Schmitt trigger less susceptible to noise.
Signal stabilization: The hysteresis also helps to stabilize the output signal in the presence of slow or gradual changes in the input signal. This is particularly useful for eliminating chattering or unwanted oscillations around the threshold levels.
Overall, a Schmitt trigger provides a robust and reliable means of converting analog input signals to digital outputs by taking advantage of hysteresis. It is widely used in digital electronics, noise filtering, signal conditioning, and applications where signal stabilization and noise rejection are crucial.