2.5 Simple systems

Fundamentals of electrical Page 1 / 1

Systems manipulate signals. There are a few simple systems which will perform simple functions upon signals. Examples include amplification (or attenuation),time-reversal, delay, and differentiation/integration.

Systems manipulate signals, creating output signals derived from their inputs. Why the following are categorized as "simple" willonly become evident towards the end of the course.

Sources

Sources produce signals without having input. We like to think of these as having controllable parameters, like amplitude andfrequency. Examples would be oscillators that produce periodic signals like sinusoids and square waves and noise generatorsthat yield signals with erratic waveforms (more about noise subsequently). Simply writing an expression for the signalsthey produce specifies sources. A sine wave generator might be specified by $y t A 2 f_{0} t u t$ , which says that the source was turned on at $t 0$ to produce a sinusoid of amplitude $A$ and frequency $f_{0}$ .

Amplifiers

An amplifier multiplies its input by a constant known as the amplifier gain .

y t G x t

The gain can be positive or negative (if negative, we would say that the amplifier inverts its input) and its magnitude can be greater than one or less than one. If less than one, the amplifieractually attenuates . A real-world example of an amplifier is your home stereo. You control the gain by turningthe volume control.

Delay

A system serves as a time delay when the output signal equals the input signal at an earlier time.

y t x t τ

Here, $τ$ is the delay. The way to understand this system is to focus on the time origin: The output at time $t τ$ equals the input at time $t 0$ . Thus, if the delay is positive, the output emerges later thanthe input, and plotting the output amounts to shifting the input plot to the right. The delay can be negative, in whichcase we say the system advances its input. Such systems are difficult to build (they would have toproduce signal values derived from what the input will be ), but we will have occasion to advance signals in time.

Time reversal

Here, the output signal equals the input signal flipped aboutthe time origin.

y t x t

Again, such systems are difficult to build, but the notion of time reversal occurs frequently in communications systems.

Mentioned earlier was the issue of whether the ordering of systems mattered. In other words, if we have two systems in cascade, does theoutput depend on which comes first? Determine if the ordering matters for the cascade of an amplifier and a delay and for the cascade of atime-reversal system and a delay.

In the first case, order does not matter; in the second it does. "Delay" means $t t τ$ . "Time-reverse" means $t t$

Case 1 $y t G x t τ$ , and the way we apply the gain and delay the signalgives the same result.

Case 2 Time-reverse then delay: $y t x t τ x t τ$ . Delay then time-reverse: $y t x t τ$ .

Got questions? Get instant answers now!

Derivative systems and integrators

Systems that perform calculus-like operations on their inputs can produce waveforms significantly different than present inthe input. Derivative systems operate in a straightforward way: A first-derivative system would have the input-outputrelationship $y t t x t$ . Integral systems have the complication that the integral'slimits must be defined. It is a signal theory convention that the elementary integral operation have a lower limit of ∞ , and that the value of all signals at $t$ ∞ equals zero. A simple integrator would have input-output relation

y t α

∞ t x α

Linear systems

Linear systems are a class of systems rather than having a specific input-output relation. Linearsystems form the foundation of system theory, and are the most important class of systems in communications. They have theproperty that when the input is expressed as a weighted sum of component signals, the output equals the same weighted sum ofthe outputs produced by each component. When $S ·$ is linear,

S G_{1} x_{1} t G_{2} x_{2} t G_{1} S x_{1} t G_{2} S x_{2} t

for all choices of signals and gains.

This general input-output relation property can be manipulated to indicate specific properties shared by all linear systems.

$S G x t G S x t$ The colloquialism summarizing this property is "Double the input, you double the output." Note that this property isconsistent with alternate ways of expressing gain changes: Since $2 x t$ also equals $x t x t$ , the linear system definition provides the same output nomatter which of these is used to express a given signal.
$S 0 0$ If the input is identically zero for all time , the output of a linear system must be zero. This property follows from the simple derivation $S 0 S x t x t S x t S x t 0$ .

Just why linear systems are so important is related not only to their properties, which are divulged throughout thiscourse, but also because they lend themselves to relatively simple mathematical analysis. Said another way, "They'rethe only systems we thoroughly understand!"

We can find the output of any linear system to a complicated input by decomposing the input into simple signals. The equation above says that when a system is linear, its output to a decomposedinput is the sum of outputs to each input. For example, if $x t t 2 f_{0} t$ the output $S x t$ of any linear system equals $y t S t S 2 f_{0} t$

Time-invariant systems

Systems that don't change their input-output relation with time are said to be time-invariant. The mathematical way ofstating this property is to use the signal delay concept described in Simple Systems .

y t S x t y t τ S x t τ

If you delay (or advance) the input, the output is similarly delayed (advanced). Thus, a time-invariant system responds toan input you may supply tomorrow the same way it responds to the same input applied today; today's output is merely delayedto occur tomorrow.

The collection of linear, time-invariant systems are the most thoroughly understood systems. Much of the signal processing and system theorydiscussed here concentrates on such systems. For example, electric circuits are, for the most part, linear andtime-invariant. Nonlinear ones abound, but characterizing them so that you can predict their behavior for any input remainsan unsolved problem.

Linear, time-invariant table
Input-Output Relation	Linear	Time-Invariant
$y t t x$	yes	yes
$y t t 2 x$	yes	yes
$y t t x 2$	no	yes
$y t t x x$	yes	yes
$y t x_{1} x_{2}$	yes	yes
$y t x t τ$	yes	yes
$y t 2 f t x t$	yes	no
$y t x t$	yes	no
$y t x^{2} t$	no	yes
$y t x t$	no	yes
$y t m x t b$	no	yes

Questions & Answers

if three forces F1.f2 .f3 act at a point on a Cartesian plane in the daigram .....so if the question says write down the x and y components ..... I really don't understand

Syamthanda Reply

hey , can you please explain oxidation reaction & redox ?

Boitumelo Reply

hey , can you please explain oxidation reaction and redox ?

Boitumelo

for grade 12 or grade 11?

Sibulele

the value of V1 and V2

Tumelo Reply

advantages of electrons in a circuit

Rethabile Reply

we're do you find electromagnetism past papers

Ntombifuthi

what a normal force

Tholulwazi Reply

it is the force or component of the force that the surface exert on an object incontact with it and which acts perpendicular to the surface

Sihle

what is physics?

Petrus Reply

what is the half reaction of Potassium and chlorine

Anna Reply

how to calculate coefficient of static friction

Lisa Reply

how to calculate static friction

Lisa

How to calculate a current

Tumelo

how to calculate the magnitude of horizontal component of the applied force

Mogano

How to calculate force

Monambi

a structure of a thermocouple used to measure inner temperature

Anna Reply

a fixed gas of a mass is held at standard pressure temperature of 15 degrees Celsius .Calculate the temperature of the gas in Celsius if the pressure is changed to 2×10 to the power 4

Amahle Reply

How is energy being used in bonding?

Raymond Reply

what is acceleration

Syamthanda Reply

a rate of change in velocity of an object whith respect to time

Khuthadzo

how can we find the moment of torque of a circular object

Kidist

Acceleration is a rate of change in velocity.

Justice

t =r×f

Khuthadzo

how to calculate tension by substitution

Precious Reply

Shongi

Leago

use fnet method. how many obects are being calculated ?

Khuthadzo

khuthadzo hii

Hulisani

how to calculate acceleration and tension force

Lungile Reply

you use Fnet equals ma , newtoms second law formula

Masego

please help me with vectors in two dimensions

Mulaudzi Reply

how to calculate normal force

Mulaudzi

Got questions? Join the online conversation and get instant answers!

Jobilize.com Reply

<< Chapter < Page Page > Chapter >>

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

100% Free Mobile Applications
Receive real-time job alerts and never miss the right job again

Source: OpenStax, Fundamentals of electrical engineering i. OpenStax CNX. Aug 06, 2008 Download for free at http://legacy.cnx.org/content/col10040/1.9

Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'Fundamentals of electrical engineering i' conversation and receive update notifications?

Ask

	4 Time reversal By OpenStax Read Online Course
	2 Amplifiers By OpenStax Read Online Course
	Capitalism Market Economy By Robert Murphy Start Test
	28 AP 28 Development Inheritance MCQ By OpenStax Start Quiz
	24 AP 24 Metabolism Nutrition Essay By OpenStax Start Flashcards
	4 AP 04 Tissue Level of Organization MCQ By OpenStax Start Quiz
	Worldport Outside By Rachel Carlisle Start Quiz
	2 Muscular System MCQ By Nick Swain Start Quiz
	Spanish (Places) By Inderjeet Brar Start Flashcards
	Computer System Engineering By Samuel Madden Start Exam
	10 Physiotherapy Modalities-Thermo By Rhodes Start Quiz
©flickr: U.S.	Biology Chapter 9 By Michael Sag Start Exam