Zero state response

One example of zero state response being used is in integrator and differentiator circuits. By examining a simple integrator circuit it can be demonstrated that when a function is put into a linear time-invariant (LTI) system, an output can be characterized by a superposition or sum of the Zero Input Response and the zero state response.

A system can be represented as

${\displaystyle f(t)\,}$    ${\displaystyle y(t)=y(t_{0})+\int _{t_{0}}^{t}f(\tau )d\tau }$ 

with the input ${\displaystyle f(t).\ }$  on the left and the output ${\displaystyle y(t).\ }$  on the right.

The output ${\displaystyle y(t).\ }$  can be separated into a zero input and a zero state solution with

${\displaystyle y(t)=\underbrace {y(t_{0})} _{Zero-input\ response}+\underbrace {\int _{t_{0}}^{t}f(\tau )d\tau } _{Zero-state\ response}.}$ 

The contributions of ${\displaystyle y(t_{0})\,}$  and ${\displaystyle f(t)\,}$  to output ${\displaystyle y(t)\,}$  are additive and each contribution ${\displaystyle y(t_{0})\,}$  and ${\displaystyle \int _{t_{0}}^{t}f(\tau )d\tau }$  vanishes with vanishing ${\displaystyle y(t_{0})\,}$  and ${\displaystyle f(t).\,}$ 

This behavior constitutes a linear system. A linear system has an output that is a sum of distinct zero-input and zero-state components, each varying linearly, with the initial state of the system and the input of the system respectively.

The zero input response and zero state response are independent of each other and therefore each component can be computed independently of the other.

The Zero State Response ${\displaystyle \int _{t_{0}}^{t}f(\tau )d\tau }$  represents the system output ${\displaystyle y(t)\,}$  when ${\displaystyle y(t_{0})=0.\,}$ 

When there is no influence from internal voltages or currents due to previously charged components

${\displaystyle y(t)=\int _{t_{0}}^{t}f(\tau )d\tau .\,}$ 

Zero state response varies with the system input and under zero-state conditions we could say that two independent inputs results in two independent outputs:

${\displaystyle f_{1}(t)\,}$  ${\displaystyle y_{1}(t)\,}$ 

and

${\displaystyle f_{2}(t)\,}$  ${\displaystyle y_{2}(t).\,}$ 

Because of linearity we can then apply the principles of superposition to achieve

${\displaystyle Kf_{1}(t)+Kf_{2}(t)\,}$  ${\displaystyle Ky_{1}(t)+Ky_{2}(t).\,}$ 

The circuit to the right acts as a simple integrator circuit and will be used to verify the equation ${\displaystyle y(t)=\int _{t_{0}}^{t}f(\tau )d\tau \,}$  as the zero state response of an integrator circuit.

Capacitors have the current-voltage relation ${\displaystyle i(t)=C{\frac {dv}{dt}}}$  where C is the capacitance, measured in farads, of the capacitor.

By manipulating the above equation the capacitor can be shown to effectively integrate the current through it. The resulting equation also demonstrates the zero state and zero input responses to the integrator circuit.

First, by integrating both sides of the above equation

${\displaystyle \int _{a}^{b}i(t)dt=\int _{a}^{b}C{\frac {dv}{dt}}dt.}$ 

Second, by integrating the right side

${\displaystyle \int _{a}^{b}i(t)dt=C[v(b)-v(a)].}$ 

Third, distribute and subtract ${\displaystyle Cv(a)\,}$  to get

${\displaystyle Cv(b)=Cv(a)+\int _{a}^{b}i(t)dt.}$ 

Fourth, divide by ${\displaystyle C\,}$  to achieve

${\displaystyle v(b)=v(a)+{\frac {1}{C}}\int _{a}^{b}i(t)dt.}$ 

By substituting ${\displaystyle t\,}$  for ${\displaystyle b\,}$  and ${\displaystyle t_{o}\,}$  for ${\displaystyle a\,}$  and by using the dummy variable ${\displaystyle \tau \,}$  as the variable of integration the general equation

${\displaystyle v(t)=v(t_{0})+{\frac {1}{C}}\int _{t_{0}}^{t}i(\tau )d\tau }$ 

is found.

The general equation can then be used to further demonstrate this verification by using the conditions of the simple integrator circuit above.

By using the capacitance of 1 farad as shown in the integrator circuit above

${\displaystyle v(t)=v(t_{0})+\int _{t_{0}}^{t}i(\tau )d\tau ,}$ 

which is the equation containing the zero input and zero state response seen at the top of the page.

To verify its zero state linearity set the voltage around the capacitor at time 0 equal to 0, or ${\displaystyle v(t_{0})=0\,}$ , meaning that there is no initial voltage. This eliminates the first term forming the equation

${\displaystyle v(t)=\int _{t_{0}}^{t}i(\tau )d\tau .\,}$ .

In accordance with the methods of linear time-invariant systems, by putting two different inputs into the integrator circuit, ${\displaystyle i_{1}(t)\,}$  and ${\displaystyle i_{2}(t)\,}$ , the two different outputs

${\displaystyle v_{1}(t)=\int _{t_{0}}^{t}i_{1}(\tau )d\tau \,}$ 

and

${\displaystyle v_{2}(t)=\int _{t_{0}}^{t}i_{2}(\tau )d\tau \,}$ 

are found respectively.

By using the superposition principle the inputs ${\displaystyle i_{1}(t)\,}$  and ${\displaystyle i_{2}(t)\,}$  can be combined to get a new input

${\displaystyle i_{3}(t)=K_{1}i_{1}(t)+K_{2}i_{2}(t)\,}$ 

and a new output

${\displaystyle v_{3}(t)=\int _{t_{0}}^{t}(K_{1}i_{1}(\tau )+K_{2}i_{2}(\tau ))d\tau .}$ 

By integrating the right side of

${\displaystyle v_{3}(t)=K_{1}\int _{t_{0}}^{t}i_{1}(\tau )d\tau +K_{2}\int _{t_{0}}^{t}i_{2}(\tau )d\tau ,}$ 

${\displaystyle v_{3}(t)=K_{1}v_{1}(t)+K_{2}v_{2}(t)\,}$ 

is found, which implies the system is linear at zero state, ${\displaystyle v(t_{0})=0\,}$ .

This entire verification example could also have been done with a voltage source in place of the current source and an inductor in place of the capacitor. We would have then been solving for a current instead of a voltage.

The circuit analysis method of breaking a system output down into a zero state and zero input response is used industry wide including circuits, control systems, signal processing, and electromagnetics. Also most circuit simulation software, such as SPICE, support the method in one form or another.