# Introduction to Signals and Systems ## Types of Signals {% hint style="info" %} #### Definition 1 A signal is a function of one or more variables {% endhint %} {% hint style="info" %} #### Definition 2 A continuous signal $$x(t)$$ maps $$\mathbb{R} \rightarrow \mathbb{R}$$ {% endhint %} {% hint style="info" %} #### Definition 3 A discrete signal $$x\[n]$$ maps $$\mathbb{Z} \rightarrow \mathbb{R}$$ {% endhint %} ### Properties of the Unit Impulse {% hint style="info" %} #### Definition 4 The unit impulse in discrete time is defined as $$\delta\[n] = \begin{cases} 1 & \text{if } n = 0\ 0 & \text{else } \end{cases}$$ {% endhint %} * $$f\[n]\delta\[n] = f\[0]\delta\[n]$$ * $$f\[t]\delta\[n-N] = f\[N]\delta\[n-N]$$ {% hint style="info" %} #### Definition 5 The unit impulse in continuous time is the dirac delta function $$\delta(t)=lim\_{\Delta\rightarrow 0}\delta\_{\Delta}(t) \qquad \delta\_{\Delta}(t)=\begin{cases} \frac{1}{\Delta}, & \text{if } 0 \leq t < \Delta \ 0 & \text{else.} \end{cases}$$ {% endhint %} * $$f(t)\delta(t) = f(0)\delta(t)$$ * $$f(t)\delta(t-\tau) = f(\tau)\delta(t-\tau)$$ * $$\delta(at) = \frac{1}{|a|}\delta(t)$$ {% hint style="info" %} #### Definition 6 The unit step is defined as $$u\[n] = \begin{cases} 1 & \text{if } n \geq 0\ 0 & \text{else.} \end{cases}$$ {% endhint %} ## Signal transformations Signals can be transformed by modifying the variable. * $$x(t - \tau)$$: Shift a signal right by $$\tau$$ steps. * $$x(-t)$$: Rotate a signal about the $$t=0$$ * $$x(kt)$$: Stretch a signal by a factor of $$k$$ These operations can be combined to give more complex transformations. For example, $$y(t) = x(\tau - t) = x(-(t-\tau))$$ flips $$x$$ and shifts it right by $$\tau$$ timesteps. This is equivalent to shifting $$x$$ left by $$\tau$$ timesteps and then flipping it. ## Convolution {% hint style="info" %} #### Definition 7 The convolution of two signals in discrete time $$(x\*h)\[n] = \sum\_{k=-\infty}^{\infty}{x\[k]h\[n-k]}$$ {% endhint %} {% hint style="info" %} #### Definition 8 The convolution of two signals in continuous time $$(x\*h)(t) = \int\_{-\infty}^{\infty}{x(\tau)h(t-\tau)d\tau}$$ {% endhint %} While written in discrete time, these properties apply in continuous time as well. * $$(x\*\delta)\[n] = x\[n]$$ * $$x\[n]\*\delta\[n-N]=x\[n-N]$$ * $$(x*h)\[n] = (h*x)\[n]$$ * $$x \* (h\_1 + h\_2) = x*h\_1 + x*h\_2$$ * $$x \* (h\_1 \* h\_2) = (x \* h\_1) \* h\_2$$ ## Systems and their properties {% hint style="info" %} #### Definition 9 A system is a process by which input signals are transformed to output signals {% endhint %} {% hint style="info" %} #### Definition 10 A memoryless system has output which is only determined by the input's present value {% endhint %} {% hint style="info" %} #### Definition 11 A causal system has output which only depends on input at present or past times {% endhint %} {% hint style="info" %} #### Definition 12 A stable system produces bounded output when given a bounded input. By extension, this means an unstable system is when $$\exists$$a bounded input that makes the output unbounded. {% endhint %} {% hint style="info" %} #### Definition 13 A system is time-invariant if the original input $$x(t)$$ is transformed to $$y(t)$$, then $$x(t-\tau)$$ is transformed to $$y(t-\tau)$$ {% endhint %} {% hint style="info" %} #### Definition 14 A system $$f(x)$$ is linear if and only if for the signals $$y\_1(t) = f(x\_1(t)), y\_2(t) = f(x\_2(t))$$, then scaling ($$f(a x\_1(t)) = a y(t)$$ and superposition ($$f(x\_1(t) + x\_2(t)) = y\_1(t) + y\_2(t)$$) hold. {% endhint %} Notice: The above conditions on linearity require that $$x(0) = 0$$ because if $$a = 0$$, then we need $$y(0) = 0$$ for scaling to be satisfied {% hint style="info" %} #### Definition 15 The impulse response of a system $$f\[x]$$ is $$h\[n] = f\[\delta\[n]]$$, which is how it response to an impulse input. {% endhint %} {% hint style="info" %} #### Definition 16 A system has a Finite Impulse Response (FIR) if $$h\[n]$$decays to zero in a finite amount of time {% endhint %} {% hint style="info" %} #### Definition 17 A system has an Infinite Impulse Response (IIR) if $$h\[n]$$does not decay to zero in a finite amount of time {% endhint %} ## Exponential Signals Exponential signals are important because they can succinctly represent complicated signals using complex numbers. This makes analyzing them much easier. $$x(t) = e^{st}, x\[n] = z^n (s, z \in \mathbb{C})$$ {% hint style="info" %} #### Definition 18 The frequency response of a system is how a system responds to a purely oscillatory signal {% endhint %}