# System Performance {% hint style="info" %} #### Definition 14 The step response of a system is how a system $$H(s)$$ responds to a step input. $$y(t) = \mathcal{L}^{-1}\left{ \frac{H(s)}{s} \right}$$ {% endhint %} ## First Order Systems {% hint style="info" %} #### Definition 15 A first order system is one with the transfer function of the form $$H(s) = \frac{s+\alpha}{s+\beta}.$$ {% endhint %} After applying partial fraction decomposition to them, their step response is of the form $$Au(t) + Be^{-\beta t}u(t).$$ Thus, the larger $$\beta$$ is (i.e the deeper in the left half plane it is), the faster the system will “settle”. ## Second Order Systems {% hint style="info" %} #### Definition 16 Second order systems are those with the transfer function in the form $$H(s) = \frac{\omega\_n^2}{s^2+2\zeta\omega\_ns+\omega\_n^2}.$$ $$\omega\_n$$ is known as the natural frequency, and $$\zeta$$is known as the damping factor. {% endhint %} Notice that the poles of the second order system are $$s = \frac{-2\zeta\omega\_n \pm \sqrt{4\zeta^2\omega^2\_n-4\omega^2\_n}}{2} = -\zeta\omega\_n \pm \omega\_n\sqrt{\zeta^2 - 1}.$$ There are four cases of interest based on $$\zeta$$. 1. **Undamped** When $$\zeta=0$$, the poles are $$s = \pm \omega\_n j$$. Because they are purely imaginary, the step response will be purely oscillatory. $$Y(s) = \frac{1}{s}\frac{\omega\_n^2}{s^2+\omega\_n^2} \leftrightarrow y(t) = u(t) - \cos(\omega\_n t)u(t)$$ 2. **Underdamped** When $$\zeta\in(0, 1)$$, the poles are $$s = -\zeta\omega\_n\pm j\omega\_n\sqrt{1-\zeta^2}$$. They are complex and in the left-half plane, so the step response will be a exponentially decaying sinusoid. We define the damped frequency $$\omega\_d = \omega\_n\sqrt{1-\zeta^2}$$ so that the poles become $$s=-\zeta\omega\_n \pm \omega\_dj$$. Notice that $$\omega\_d < \omega\_n$$. If we compute the time-response of the system, $$y(t) = \left\[ 1 - \frac{e^{-\zeta\omega\_nt}}{\sqrt{1-\zeta^2}}\cos\left(\omega\_d t - \arctan\left( \frac{\zeta}{\sqrt{1-\zeta^2}} \right)\right)\right]u(t)$$ 3. **Critically Damped** When $$\zeta=1$$, both poles are at $$s=-\omega\_n$$. The poles are both real, so the time-response will respond without any overshoot. 4. **Overdamped** When $$\zeta>1$$, the poles are $$-\zeta\omega\_n\pm \omega\_n\sqrt{\zeta^2-1}$$. Both of these will be real, so the time-response will look similar to a first-order system where it is slow and primarily governed by the slowest pole. ### The Underdamped Case If we analyze the underdamped case further, we can first look at its derivative. $$\begin{aligned} sY(s) &= \frac{\omega\_n^2}{s^2+2\zeta\omega\_ns+\omega\_n^2} = \frac{\omega\_n^2}{\omega\_d} \frac{\omega\_d}{(s+\zeta\omega\_n)^2+\omega\_d^2}\ \therefore \frac{d^{}y}{dt^{}} &= \frac{\omega\_n^2}{\omega\_d}e^{-\zeta\omega\_nt}\sin(\omega\_d t)u(t) \qquad (8)\end{aligned}$$ {% hint style="info" %} #### Definition 17 The Time to Peak ($$T\_p$$) of a system is how long it takes to reach is largest value in the step response. {% endhint %} Using Equation 8, we see that the derivative is first equal to 0 when $$t = \frac{\pi}{\omega\_d}$$. $$\therefore T\_p = \frac{\pi}{\omega\_d}$$ {% hint style="info" %} #### Definition 18 The Percent Overshoot ($$% O.S$$) of a system is by how much it will overshoot the step response. {% endhint %} The percent overshoot occurs at $$t = \frac{\pi}{\omega\_d}$$, so $$% O.S = e^{-\zeta\omega\_n \frac{\pi}{\omega\_d}} = e^{\frac{-\zeta\pi}{\sqrt{1-\zeta^2}}}.$$ {% hint style="info" %} #### Definition 19 The Settling Time ($$T\_s$$) of a system is how long it takes for the system to start oscillating within 2\\% of its final value. {% endhint %} $$\begin{aligned} |y(T\_s) - 1| < 0.02 \implies \frac{e^{-\zeta\omega\_nT\_s}}{\sqrt{1-\zeta^2}} = 0.02\ \therefore T\_s = -\frac{1}{\zeta\omega\_n} \ln(0.02 \sqrt{1-\zeta^2})\end{aligned}$$ Since our poles are complex, we can represent them in their polar form. $$\begin{aligned} r = \omega\_d^2 + \zeta^2 + \omega\_n^2 = \omega\_n^2(1-\zeta^2)+\zeta^2\omega\_n^2 = \omega\_n^2\ \cos(\pi-\theta) = \frac{-\zeta\omega\_n}{\omega\_n} = -\zeta\\\end{aligned}$$ What this tells us is that if we search along the vector at angle $$\pi-\theta$$, we get a constant $$\zeta$$. ### Additional Poles and Zeros of a Second Order System Suppose we added an additional pole to the second order system so its transfer function was instead $$H(s) = \frac{bc}{(s+c)(s^2+2as+b)}.$$ Then its step response will be $$\begin{aligned} Y(s) &= \frac{1}{s}+\frac{D}{s+c}+\frac{Bs+C}{s^2+as+b}\ B &= \frac{c(a-c)}{c^2+b-ca}\quad C = \frac{c(a^2-ac-b)}{c^2+b-ca} \quad D = \frac{-b}{c^2-ac+b}.\end{aligned}$$ Notice that $$\lim\_{c\to\infty} D = 0 \quad \lim\_{c\to\infty} B = -1 \lim\_{c\to\infty} C = -a.$$ In other words, as the additional pole moves to infinity, the system acts more and more like a second-order. As a rule of thumb, if $$Re{c}\geq5Re{a}$$, then the system will approximate a second order system. Because of this property, we can often decompose complex systems into a series of first and second order systems. If we instead add an additional zero to the second order system so its transfer function looks like $$H(s) = \frac{s+a}{s^2+2\zeta\omega\_n+\omega\_n^2}$$ and its step response will look like $$sY(s) + aY(s).$$ Thus if $$a$$ is small, then the effect of the zero is similar to introducing a derivative into the system, whereas if $$a$$ is large, then the impact of the zero is primarily to scale the step response. One useful property about zeros is that if a zero occurs close enough to a pole, then they will “cancel” each other out and that pole will have a much smaller effect on the step response. ## Stability Recall Equation 7 which told us the time-domain solution to state-space equations was $$\mathbf{x}(t) = e^{At}\mathbf{x}(0) + \int\_{0}^{t}e^{A(t-\tau)}B\mathbf{u}(\tau)d\tau.$$ {% hint style="info" %} #### Definition 20 A system is bounded-input, bounded output(BIBO) stable if $$\exists K\_u, K\_x < \infty$$ such that $$|\mathbf{u}(t)| < K\_{u} \implies |\mathbf{x}(t)| < K\_x$$. {% endhint %} Following from Definition 20, Equation 7, this means that $$\lim\_{t\to\infty}\mathbf{x}(t) = \boldsymbol{0}.$$ If instead $$\lim\_{t\to\infty}\mathbf{x}(t) = \infty$$, then the system is unstable. {% hint style="info" %} #### Theorem 3 If all poles are in the left half plane and the number of zeros is less than or equal to the number of poles, then the system is BIBO stable. {% endhint %} {% hint style="info" %} #### Definition 21 A system is called marginally stable if the zero-input response does not converge to $$\boldsymbol{0}$$. {% endhint %} {% hint style="info" %} #### Theorem 4 A system is marginally stable if there is exactly one pole at $$s=0$$ or a pair of poles at $$s=\pm j\omega\_0$$. {% endhint %} In all other cases, the system will be unstable. ## Steady State Error Consider the unity feedback loop depicted in Figure 4 where we put a system $$G(s)$$ in unity feedback to control it. ![Figure 4: Unity Feedback Loop](https://3896527066-files.gitbook.io/~/files/v0/b/gitbook-x-prod.appspot.com/o/spaces%2F-MQYqMkpf2WPiP6MKWRe%2Fuploads%2Fgit-blob-abae93dc69ebb1e82015401a56a532acfe3e5f13%2Fa86379e5b5f70b90f28ee748670e88f225367c40.png?alt=media) We want to understand what its steady state error will be in response to different inputs. {% hint style="info" %} #### Theorem 5 The final value theorem says that for a function whose unilateral laplace transform has all poles in the left half plane, $$\lim\_{t\to\infty}x(t) = \lim\_{s\to0} sX(s).$$ {% endhint %} Using this fact, we see that for the unity feedback system, $$E(s) = \frac{R(s)}{1+G(s)}.$$ Using these, we can define the static error constants. {% hint style="info" %} #### Definition 22 The position constant determines how well a system can track a unit step. $$K\_p = \lim\_{s\to0}G(s) \qquad (9)$$ $$\lim\_{t\to\infty} e(t) = \lim\_{s\to0} s \frac{1}{s} \frac{1}{1+G(s)} = \frac{1}{1+K\_p}$$ {% endhint %} {% hint style="info" %} #### Definition 23 The velocity constant determines how well a system can track a ramp. $$K\_v = \lim\_{s\to0}sG(s) \qquad (10)$$ $$\lim\_{t\to\infty} e(t) = \lim\_{s\to0} s \frac{1}{s^2} \frac{1}{1+G(s)} = \frac{1}{K\_v}$$ {% endhint %} {% hint style="info" %} #### Definition 24 The acceleration constant determines how well a system can track a parabola. $$K\_a = \lim\_{s\to0}s^2G(s) \qquad (11)$$ $$\lim\_{t\to\infty} e(t) = \lim\_{s\to0} s \frac{1}{s^3} \frac{1}{1+G(s)} = \frac{1}{K\_a}$$ {% endhint %} Notice that large static error constants mean a smaller error. Another observation we can make is that if a system has $$n$$ poles at $$s=0$$, it can perfectly track an input whose laplace transform is $$\frac{1}{s^{n-k}}$$ for $$k\in\[0, n-1]$$. We give $$n$$ a formal name. {% hint style="info" %} #### Definition 25 The system type is the number of poles at 0. {% endhint %} This also brings another observation. {% hint style="info" %} #### Definition 26 The internal model principle is that if the system in the feedback loop has a model of the input we want to track, then it can track it exactly. {% endhint %} If instead we have a state-space system, then assuming the system is stable, $$\lim\_{t\to\infty}\frac{d^{}\mathbf{x}}{dt^{}} = \boldsymbol{0} \implies \lim\_{t\to\infty}\mathbf{x} = \mathbf{x}\_{ss}.$$ Applying this to the state space equations for a step input, $$\frac{d^{}\mathbf{x}}{dt^{}} = \boldsymbol{0} = A\mathbf{x}*{ss} + B\cdot I \implies \mathbf{x}*{ss} = -A^{-1}B \qquad (12)$$ Looking at the error between the reference and the output in the 1D input case, $$\mathbf{e}(t) = \mathbf{r}(t) - \mathbf{y}(t) = 1 - C\mathbf{x}\_{ss} = 1 + CA^{-1}B.$$ ## Margins ![Figure 5: Frequency Response](https://3896527066-files.gitbook.io/~/files/v0/b/gitbook-x-prod.appspot.com/o/spaces%2F-MQYqMkpf2WPiP6MKWRe%2Fuploads%2Fgit-blob-47d7e5411863215c591677e9dcd94459dc96fac8%2F26be685aa86914d15af1c8cc7569c6acf97a401a.png?alt=media) If we take a complex exponential and pass it into a causal LTI system with impulse response $$g(t)$$, then $$y(t) = e^{j\omega t} \* g(t) = \int\_{-\infty}^{\infty}g(\tau)e^{j\omega(t-\tau)}d\tau = e^{j\omega t} \int\_{0}^{\infty}g(\tau)e^{-j\omega \tau}d\tau.$$ This shows us that $$e^{j\omega t}$$ is an eigenfunction of the system. {% hint style="info" %} #### Definition 27 The frequency response of the system determines how it scales pure frequencies. It is equivalent to the Laplace transform evaluated on the imaginary axis. $$G(j\omega) = \int\_0^{\infty}g(\tau)e^{-j\omega\tau}d\tau \qquad (13)$$ {% endhint %} Suppose we put a linear system $$G(s)$$ in negative feedback. We know that if $$\angle G(j\omega) = (2k+1)\pi$$ for some $$k\in\mathbb{Z}$$, then the output of the plant will be $$-|G(j\omega)|e^{j\omega t}$$. If $$|G(j\omega)| \geq 1$$, then this will feed back into the error term where it will be multiplied by $$|G(j\omega)|$$ repeatedly, and this will cause the system to be unstable because $$|G(j\omega)|\geq1$$ and thus will not decay. {% hint style="info" %} #### Definition 28 The gain margin $$G\_m$$is the change in the open loop gain required to make the closed loop system unstable. {% endhint %} {% hint style="info" %} #### Definition 29 The phase margin $$\phi\_m$$is the change in the open loop phase required to make the closed loop system unstable. {% endhint %} We can imagine the gain and phase margin like placing a “virtual box” before the plant as shown in Figure 6. ![Figure 6: The Gain and Phase Margin virtual system](https://3896527066-files.gitbook.io/~/files/v0/b/gitbook-x-prod.appspot.com/o/spaces%2F-MQYqMkpf2WPiP6MKWRe%2Fuploads%2Fgit-blob-78f76cf0bc5855c3b4b54bba911fca734822b132%2F8832ffa2bd68ff136387cb6f3537f0c6815bbdfd.png?alt=media) The characteristic polynomial of the closed loop transfer function is $$1 + G\_me^{-j\phi\_m}G(s) = 0.$$ At the gain margin frequency $$\omega\_{gm}$$, $$|G\_m||G(j\omega\_{gm})| = 1 \implies |G\_m| = \frac{1}{|G(j\omega\_{gm})|}.$$ where the gain margin frequency is $$\angle G(j\omega\_m) = (2k+1)\pi$$ for $$k\in\mathbb{Z}$$. Likewise, at the phase margin frequency $$\omega\_{pm}$$, $$1 + G\_me^{-j\omega\_m}G(j\omega\_{pm}) = 0 \implies -\phi\_m + \angle G(j\omega\_{pm}) = (2k+1)\pi.$$ where the phase margin frequency is $$|G(j\omega\_{pm})| = 1$$. Notice that if there is a time delay of $$T$$ in the system, the phase margin will remain unchanged since the magnitude response will be the same, but the gain margin will change because the new phase will be $$\angle G(j\omega) - \omega T.$$