9.6:

Transfer function and Bode Plots-II

JoVE Core
Electrical Engineering
Un abonnement à JoVE est nécessaire pour voir ce contenu.  Connectez-vous ou commencez votre essai gratuit.
JoVE Core Electrical Engineering
Transfer function and Bode Plots-II

19 Views

01:23 min

July 08, 2024

In the standard form, the transfer function is shown in constant gain, poles/zeros at origin, simple poles/zeros, and quadratic poles/zeros; each contributing uniquely to the system's overall response. The term represents the magnitude of the simple zero:

Equation 1

The Bode magnitude plot remains flat at low frequencies (approaching 0 dB) and begins to ascend at 20 dB/decade after a specific frequency known as the corner or break frequency, ω1. This is the frequency where the magnitude plot's slope changes and the actual response begins to deviate from the straight-line approximation. This deviation is quantified as 3 dB at ω=ω1.

The phase angle ϕ, expressed as:

Equation 2

Phase angle starts at 0° and approaches 90° asymptotically as the frequency increases. For frequencies much lower than the corner frequency (ω≪ω1), the term jω/ω1 is very small, so the magnitude is negligible, and the phase is essentially zero. As the frequency approaches ω1, leading to a -3 dB point in magnitude and a phase angle of 45°. For frequencies much higher than ω1 (ω≫ω1), the magnitude's slope changes to 20 dB/decade, and the phase settles at 90°.

Figure 1

Quadratic pole/zero:

The magnitude and phase angle of a quadratic pole is:

Equation 3

Equation 4

The amplitude plot for a quadratic pole has two parts: a flat response below the natural frequency ωn, and a -40 dB/decade slope above ωn, with the actual plot's peak varying with the damping factor ζ2. The phase plot for a quadratic pole decreases linearly with a slope of -90° per decade, starting at one-tenth of the natural frequency and ending at ten times that, influenced by the damping factor ζ2.