Highpass filter

A highpass filter passes signal frequencies above a cutoff and attenuates lower frequencies. The simplest first-order highpass has transfer function

$H (s) = \frac{s}{s + ω _{c}}, H (jω) = \frac{jω}{jω + ω _{c}} .$

Behavior

At DC ( $ω = 0$ ): $H (0) = 0$ . DC is completely blocked — the filter is AC-coupled.
As $ω \to \infty$ : $∣ H (jω) ∣ \to 1$ . High frequencies pass unattenuated.
At $ω = ω_{c}$ : $∣ H (j ω_{c}) ∣ = 1/ 2$ — the half-power cutoff, a $3 dB$ drop, same as for the lowpass.

Pole-zero structure

Same pole as the lowpass at $s = - ω_{c}$ , plus a zero at $s = 0$ . The zero at the origin is what kills the DC component — the numerator $s$ goes to zero when $s = 0$ .

The pattern: an extra zero at the origin transforms a lowpass into a highpass with the same cutoff.

LPF + HPF = 1

There’s a clean conceptual identity:

$HPF (s) + LPF (s) = \frac{s}{s + ω _{c}} + \frac{ω _{c}}{s + ω _{c}} = \frac{s + ω _{c}}{s + ω _{c}} = 1.$

The highpass and lowpass at the same cutoff preserve the whole signal between them. Conservation of frequency content.

Bode plot

Asymptotic magnitude: starts at $- \infty dB$ at $ω = 0$ , rising at $+ 20 dB/decade$ at low frequencies due to the zero at origin, then flattening at $0 dB$ past $ω = ω_{c}$ where the pole’s $- 20 dB/decade$ slope cancels the zero’s $+ 20$ . So below $ω_{c}$ , magnitude rises; above $ω_{c}$ , magnitude is flat at $0 dB$ .

Phase: starts at $+ 90°$ at very low frequencies (from the zero at origin), transitions through $+ 45°$ at $ω = ω_{c}$ , and asymptotes to $0°$ at high frequencies. Decreasing from $+ 90°$ to $0°$ over the transition.

Where it’s used

Audio coupling: a highpass blocks DC offsets between amplifier stages. Common in microphone preamps and signal-conditioning circuits.
AC-coupling capacitors: a series capacitor in a circuit forms a highpass with the load resistance, blocking DC bias while passing the AC signal.
Rumble filter: a low-frequency rumble (e.g. footsteps in a recording studio) is removed by a highpass at ~30 Hz.
DC removal in measurement systems: a highpass strips off DC drift while preserving the AC signal of interest.

Circuit realisation (Electronics I)

The concrete first-order highpass in electronics is the RC highpass filter: a series capacitor feeding a shunt resistor, output across the resistor, with Cutoff frequency $f_{c} = 1/ (2 π RC)$ and a $+ 20 dB/decade$ rise below it. This is exactly the Coupling capacitor used between amplifier stages — it blocks the DC bias while passing the AC signal, and its cutoff sets the low-frequency end of the amplifier’s useful range.

Idriss Rami — Notes

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