Implement series RLC branch

Fundamental Blocks/Elements

The Series RLC Branch block implements a single resistor, inductor,
or capacitor, or a series combination of these. Use the **Branch
type** parameter to select elements you want to include in
the branch.

Negative values are allowed for resistance, inductance, and capacitance.

**Branch type**Select the elements you want to include in the branch. The

**R**letter defines the resistor, the**L**letter defines the inductor, and the**C**letter defines the capacitor. Select**Open circuit**to define an open circuit (R=0, L=0, C=inf). Only existing elements are displayed in the block icon. Default is`RLC`

.**Resistance**The branch resistance, in ohms (Ω). Default is

`1`

. The**Resistance**parameter is not visible if the resistor element is not specified in the**Branch type**parameter.**Inductance**The branch inductance, in henries (H). Default is

`1e-3`

. The**Inductance**parameter is not visible if the inductor element is not specified in the**Branch type**parameter.**Set the initial inductor current**If selected, the initial inductor current is defined by the

**Inductor initial current**parameter. If cleared, the software calculates the initial inductor current in order to start the simulation steady-state. Default is cleared.The

**Set the initial inductor current**parameter is not visible and has no effect on the block if the inductor element is not specified in the**Branch type**parameter.**Inductor initial current (A)**The initial inductor current used at the start of the simulation. This parameter is not visible and has no effect on the block if the inductor is not modeled and if the

**Set the initial inductor current**parameter is not selected. Default is`0`

.**Capacitance**The branch capacitance, in farads (F). Default is

`1e-6`

. The**Capacitance**parameter is not visible if the capacitance element is not specified in the**Branch type**parameter.**Set the initial capacitor voltage**If selected, the initial capacitor voltage is defined by the

**Capacitor initial voltage**parameter. If cleared, the software calculates the initial capacitor voltage in order to start the simulation in steady-state. Default is cleared.The

**Set the initial capacitor voltage**parameter is not visible and have no effect on the block if the capacitor element is not specified in the**Branch type**parameter.**Capacitor initial voltage (V)**The initial capacitor voltage used at the start of the simulation. The

**Capacitor initial voltage**parameter is not visible and have no effect on the block if the capacitor is not modeled and if the**Set the initial capacitor voltage**parameter is not selected.**Measurements**Select

`Branch voltage`

to measure the voltage across the Series RLC Branch block terminals.Select

`Branch current`

to measure the current flowing through the Series RLC Branch block.Select

`Branch voltage and current`

to measure the voltage and the current of the Series RLC Branch block.Default is

`None`

.Place a Multimeter block in your model to display the selected measurements during the simulation. In the

**Available Measurements**list box of the Multimeter block, the measurement is identified by a label followed by the block name.Measurement

Label

Branch voltage

`Ub:`

Branch current

`Ib:`

Obtain the frequency response of a fifth-harmonic filter (tuned
frequency = 300 Hz) connected on a 60 Hz power system. This example
is available in the `power_seriesbranch`

model.

The network impedance in the Laplace domain is

$$Z(s)=\frac{V(s)}{I(s)}=\frac{LC{s}^{2}+RCs+1}{Cs}.$$

To obtain the frequency response of the impedance you have to get the state-space model (A B C D matrices) of the system.

This system is a one-input (Vsource) and one-output (Current Measurement block) system.

If you have Control System
Toolbox™ software installed, you
can use the `bode`

function to get the transfer function *Z(s)* from
the state-space matrices as follows:

[A,B,C,D] = power_analyze('power_seriesbranch'); freq = logspace(1,4,500); w = 2*pi*freq; [Ymag,Yphase] = bode(A,B,C,D,1,w); % invert Y(s) to get Z(s) Zmag = 1./Ymag; Zphase = -Yphase; subplot(2,1,1) loglog(freq,Zmag) grid title('5th harmonic filter') xlabel('Frequency, Hz') ylabel('Impedance Zmag') subplot(2,1,2) semilogx(freq,Zphase) xlabel('Frequency, Hz') ylabel('phase Z') grid

You can also use the Impedance Measurement block and the Powergui block to plot the impedance as a function of frequency. In order to measure the impedance you must disconnect the voltage source.

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