A band-reject filter, also known as a notch filter or band-stop filter, is designed to attenuate or block specific frequencies within a certain range, while allowing all other frequencies to pass through relatively unaltered. This type of filter is useful for removing or reducing unwanted signals or interference within a specific frequency band.
Band-reject filters typically consist of passive components like resistors, capacitors, and inductors arranged in a specific configuration. The most common design is an RLC circuit, which includes a resistor (R), an inductor (L), and a capacitor (C). The filter's characteristics are determined by the values of these components and their arrangement.
Here's a simplified explanation of how a band-reject filter works:
Resonance: The band-reject filter is designed to have a resonant frequency, which is the frequency at which the filter exhibits the maximum attenuation. At this resonant frequency, the filter impedance is high, causing the signal to experience significant resistance or impedance, resulting in a reduction of that specific frequency.
Low-pass and High-pass filtering: The RLC circuit used in the band-reject filter can be thought of as combining both a low-pass filter (allowing frequencies below a certain cutoff) and a high-pass filter (allowing frequencies above a certain cutoff).
Frequency selection: The values of the inductor (L), capacitor (C), and resistor (R) are chosen to create a specific resonant frequency in the band where you want to block the signals. The resonant frequency is given by the formula:
f_resonant = 1 / (2 * π * √(L * C))
By adjusting the values of L and C, you can select the frequency at which the filter blocks signals.
Attenuation: At frequencies close to the resonant frequency, the filter exhibits high impedance due to the energy exchange between the capacitor and inductor. This leads to significant attenuation, effectively blocking the passage of signals at or near the resonant frequency.
Passband and stopband: The frequencies outside the vicinity of the resonant frequency are considered the passband, where the filter allows signals to pass through relatively unaltered. On the other hand, the frequencies in the vicinity of the resonant frequency make up the stopband, where the filter attenuates or blocks the signals.
Overall, the band-reject filter's ability to block specific frequencies is achieved by exploiting the resonance properties of the RLC circuit, which causes a high impedance at the chosen resonant frequency, leading to attenuation of signals in that range.