Laplace Transforms
Laplace Transform in Circuit Analysis
The Laplace transform* is a technique for analyzing linear time-invariant systems such as electrical circuits It provides an alternative functional description that often simplifies:
The process of analyzing the behaviour of the systemThe synthesis of a new system based on a set of specifications
* After Pierre-Simon Laplace (1749 – 1827)
Laplace Transforms
Mechatronic System
Mechanical System
Sensors
Actuators
Output Signal Conditioning& Interfacing
Input Signal Conditioning& Interfacing
Operator
Display System
Control Architecture
Laplace Transforms
Introduction to Transformations
A mathematical transformation employs rules to change the form of data without altering its meaningPopular transformations used in signals
Fourier (suited to solving problems where input domain is either repetitive or if the input is on a loop)Z (suited for problems where the input is discrete instead of continuous)Laplace (suited to solving problems with known initial values)
02-01-ImplantDefribillator.wmv
Laplace Transforms
Laplace Transform
A powerful tool for circuit analysisThe steps involved are
A set of differential equations describing a circuit converted to the complex frequency domainThe variables of interest are solvedConvert from frequency domain back to time domain
Laplace Transforms
Implant Defibrillator ProblemImplant defibrillator manufacturer Guidant found that the close spacing between a wire and device component could potentially arc between them and cause a short circuitIn March 2005, a 21-year-old college student who had a Guidant defibrillator implanted in his chest died suddenlyThe type of defibrillator in his death was short-circuiting at a rate of about once a month from 2003 to 2004; but this finding was not reported until February 2005
Laplace Transforms
Breadboard (protoboard)A breadboard (protoboard) is a construction base for a one-of-a-kind electronic circuit, a prototype. Because the solderless breadboard does not require soldering, it is reusable, and thus can be used for temporary prototypes and experimenting with circuit design more easily.
A breadboard with a completed circuit
Laplace Transforms
Printed Circuit BoardsPrinted circuit boards (PCBs) are used to mechanically support and electrically connect electronic components using conductive pathways, or traces, etched from copper sheets laminated onto a non-conductive substrate.
PCB for mobile phones
Laplace Transforms
Printed Circuit Board DesignPrinted circuit board designs are normally very complex. Hence, this is normally done on computer software developed for this purpose. Most such software are able to perform auto-routing.
Screenshot of PCB design software
02-02-DNA_Circuits.wmv
Laplace Transforms
Soldering
Electrical components need to be physically attached to the right locations on the printed circuit board. This is accomplished using soldering.
Laplace Transforms
Surface Mount TechnologySurface mount technology (SMT) is a method for constructing electronic circuits in which the components are mounted directly onto the surface of printed circuit boards (PCBs). Electronic devices so made are called surface-mount devices or SMDs. In the industry it has largely replaced the previous construction method of fitting components with wire leads into holes in the circuit board (also called through-hole technology).
02-03-WedgeBonding.wmv02-04-BallBonding.wmv
Laplace Transforms
Definition of Laplace Transform
∫∞ −==0
)()()( dtetfsFtfL st
ω+σ= js
[ ] ∫∞+α
∞+α
−
π==
j
j
st dsesFj
tfsFL )(21)()(1
Laplace Transform is defined as
s is a complex variable given by
The inverse Laplace transform is defined as
A list of Laplace transform pairs
Uniqueness of Laplace Transform enables us to avoid the complex integration
Laplace Transforms
Laplace Transform Properties (1)Linearity:
Scaling:
Laplace Transforms
Laplace Transform Properties (2)Time Shift:
u(t-a) = 0 for t<a and u(t-a) = 1 for t>a
Frequency Shift:
Laplace Transforms
Laplace Transform Properties (3)
Time Differentiation:
Integrating by parts
With one more differentiation
In the general case
Laplace Transforms
Laplace Transform Properties (4)
Time Integration:
Integrating by parts
The first term is zero
Laplace Transforms
Laplace Transform Properties (5)
Frequency Differentiation:
Taking derivative wrt x
Laplace Transforms
Laplace Transform Properties (6)
Time Periodicity:
With the time-shift property
Using the identity
Periodic function
Decomposition of periodic function
The transform of a periodic function is the transform of the first period of the function divided by 1 – e-Ts
Laplace Transforms
Laplace Transform PropertiesSummary
The properties of the Laplace Transform allow us to obtain transform properties without performing the integral.
Laplace Transforms
Laplace Transform of Circuit Elements
ssFtfL
t )()(0
=⎥⎦⎤
⎢⎣⎡∫∫
∞
=0
)(1)( dttiC
tv
)(11)( sIsC
sV =
Voltage Source
CssIsVsZC
1)()()( ==
)()( tidtdLtV = )0()()( FssFtf
dtdL −=⎥⎦
⎤⎢⎣⎡
LssIsVsZL ==)()()(
ssV 1)( = RZR =Resistor
Capacitor
Inductor
)()( ssLIsV =
Laplace Transforms
Laplace Transforms
Transfer Function
)()()(
sXsYsH =
For excitation X(s) and response Y(s) in the complex frequency domain. The transfer function is given by
The transfer function of a circuit describes how the output behaves with respect to the input. It also indicates how a signal is processed as it passes through a network.
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