Laplace transform Guide, Meaning , Facts, Information and Description
In mathematics and in particular, in functional analysis, the Laplace transform of a function f(t) defined for all real numbers t ≥ 0 is the function F(s), defined by:
Also, the output of a linear dynamic system can be calculated by convolving its unit impulse response with the input signal. Performing this calculation in Laplace space turns the convolution into a multiplication, which often makes matters easier. For more information, see control theory.
The Laplace transform is named in honor of Pierre-Simon Laplace.
A sometimes convenient abuse of notation, prevailing especially among engineers and physicists, writes this in the following form:
The Laplace transform can also be used to solve differential equations and is used extensively in electrical engineering.
An interesting aspect of Laplace transforms is that mathematicians to this day do not know its domain. In other words, there is no specific set of rules that one can check a function against to know if its Laplace transform can be taken.
Properties
Linearity
nth power
Exponential
Sine
Cosine
Hyperbolic sine
Hyperbolic cosine
Natural logarithm
nth root
Bessel function of the first kind
Modified Bessel function of the first kind
Error function
Differentiation
Integration
s shifting
t shifting
Note: is the step function.nth-power shifting
Convolution
Laplace transform of a function with period p
In mathematics and in particular, in functional analysis, the Laplace transform of a function f(t) defined for all real numbers t ≥ 0 is the function F(s), defined by:
This integral transform has a number of properties that make it useful for analysing linear dynamic systems. The most significant advantage is that integration and differentiation become multiplication and division. (This is similar to the way that logarithms change multiplication of numbers to addition.) This changes integral equations and differential equations to polynomial equations, which are much easier to solve. The inverse is the Bromwich integral, which is a complex integral.
Also, the output of a linear dynamic system can be calculated by convolving its unit impulse response with the input signal. Performing this calculation in Laplace space turns the convolution into a multiplication, which often makes matters easier. For more information, see control theory.
The Laplace transform is named in honor of Pierre-Simon Laplace.
A sometimes convenient abuse of notation, prevailing especially among engineers and physicists, writes this in the following form:
The Laplace transform can also be used to solve differential equations and is used extensively in electrical engineering.
An interesting aspect of Laplace transforms is that mathematicians to this day do not know its domain. In other words, there is no specific set of rules that one can check a function against to know if its Laplace transform can be taken.
Properties
Linearity
nth power
Exponential
Sine
Cosine
Hyperbolic sine
Hyperbolic cosine
Natural logarithm
nth root
Bessel function of the first kind
Modified Bessel function of the first kind
Error function
Differentiation
Integration
s shifting
t shifting
Note: is the step function.nth-power shifting
Convolution
Laplace transform of a function with period p
Other common transforms
| Laplace transform | Time function |
| , unit step | |
Relation to other transforms
The Laplace transform is closely related to the Fourier transform and the z-transform.
In particular, the Fourier transform can be seen as a specialized Laplace transform using the rule s = it.
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