Linear System: Difference between revisions

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=== 2012 ===
=== 2012 ===
* http://en.wikipedia.org/wiki/Linear_system
* http://en.wikipedia.org/wiki/Linear_system
** A '''linear system</B> is a mathematical model of a [[system]] based on the use of a [[linear operator]]. Linear systems typically exhibit features and properties that are much simpler than the general, [[nonlinear]] case. As a mathematical abstraction or idealization, linear systems find important applications in [[automatic control]] theory, [[signal processing]], and [[telecommunications]]. For example, the propagation medium for wireless communication systems can often be modeled by linear systems.        <P>             A general [[deterministic system (mathematics)|deterministic system]] can be described by operator, <math>H</math>, that maps an input, <math>x(t)</math>, as a function of <math>t</math> to an output, <math>y(t)</math>, a type of [[Black box (systems)|black box]] description.  Linear systems satisfy the properties of [[Superposition principle|superposition]] and [[scaling]] or [[Homogeneous_function|homogeneity]]. Given two valid inputs  :<math>x_1(t) \,</math> :<math>x_2(t) \,</math> as well as their respective outputs :<math>y_1(t) = H \left \{ x_1(t) \right \} </math> :<math>y_2(t) = H \left \{ x_2(t) \right \} </math> then a linear system must satisfy :<math>\alpha y_1(t) + \beta y_2(t) = H \left \{ \alpha x_1(t) + \beta x_2(t) \right \} </math> for any [[scalar (mathematics)|scalar]] values <math>\alpha \,</math> and <math>\beta \,</math>.        <P>            The behavior of the resulting system subjected to a complex input can be described as a sum of responses to simpler inputs.  In nonlinear systems, there is no such relation.        <P>            This mathematical property makes the solution of modelling equations simpler than many nonlinear systems. For [[time-invariant system|time-invariant]] systems this is the basis of the [[impulse response]] or the [[frequency response method]]s (see [[LTI system theory]]), which describe a general input function <math>x(t)</math> in terms of unit [[Dirac's delta function|impulses]] or [[frequency components]].        <P>            Typical [[differential equation]]s of linear [[time-invariant system|time-invariant]] systems are well adapted to analysis using the [[Laplace transform]] in the [[continuous function|continuous]] case, and the [[Z-transform]] in the [[discrete mathematics|discrete]] case (especially in computer implementations).        <P>            Another perspective is that solutions to linear systems comprise a system of [[function (mathematics)|function]]s which act like [[vector (geometric)|vector]]s in the geometric sense.        <P>            A common use of linear models is to describe a nonlinear system by [[linearization]].  This is usually done for mathematical convenience.
** A '''linear system</B> is a mathematical model of a [[system]] based on the use of a [[linear operator]]. Linear systems typically exhibit features and properties that are much simpler than the general, [[nonlinear]] case. As a mathematical abstraction or idealization, linear systems find important applications in [[automatic control]] theory, [[signal processing]], and [[telecommunications]]. For example, the propagation medium for wireless communication systems can often be modeled by linear systems.        <P> A general [[deterministic system (mathematics)|deterministic system]] can be described by operator, <math>H</math>, that maps an input, <math>x(t)</math>, as a function of <math>t</math> to an output, <math>y(t)</math>, a type of [[Black box (systems)|black box]] description.  Linear systems satisfy the properties of [[Superposition principle|superposition]] and [[scaling]] or [[Homogeneous_function|homogeneity]]. Given two valid inputs  :<math>x_1(t) \,</math> :<math>x_2(t) \,</math> as well as their respective outputs :<math>y_1(t) = H \left \{ x_1(t) \right \} </math> :<math>y_2(t) = H \left \{ x_2(t) \right \} </math> then a linear system must satisfy :<math>\alpha y_1(t) + \beta y_2(t) = H \left \{ \alpha x_1(t) + \beta x_2(t) \right \} </math> for any [[scalar (mathematics)|scalar]] values <math>\alpha \,</math> and <math>\beta \,</math>.        <P>            The behavior of the resulting system subjected to a complex input can be described as a sum of responses to simpler inputs.  In nonlinear systems, there is no such relation.        <P>            This mathematical property makes the solution of modelling equations simpler than many nonlinear systems. For [[time-invariant system|time-invariant]] systems this is the basis of the [[impulse response]] or the [[frequency response method]]s (see [[LTI system theory]]), which describe a general input function <math>x(t)</math> in terms of unit [[Dirac's delta function|impulses]] or [[frequency components]].        <P>            Typical [[differential equation]]s of linear [[time-invariant system|time-invariant]] systems are well adapted to analysis using the [[Laplace transform]] in the [[continuous function|continuous]] case, and the [[Z-transform]] in the [[discrete mathematics|discrete]] case (especially in computer implementations).        <P>            Another perspective is that solutions to linear systems comprise a system of [[function (mathematics)|function]]s which act like [[vector (geometric)|vector]]s in the geometric sense.        <P>            A common use of linear models is to describe a nonlinear system by [[linearization]].  This is usually done for mathematical convenience.


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Latest revision as of 18:19, 2 June 2024

A Linear System is a mathematical model that is based on the use of a linear operator.



References

2015

2012

  • http://en.wikipedia.org/wiki/Linear_system
    • A linear system is a mathematical model of a system based on the use of a linear operator. Linear systems typically exhibit features and properties that are much simpler than the general, nonlinear case. As a mathematical abstraction or idealization, linear systems find important applications in automatic control theory, signal processing, and telecommunications. For example, the propagation medium for wireless communication systems can often be modeled by linear systems.

      A general deterministic system can be described by operator, [math]\displaystyle{ H }[/math], that maps an input, [math]\displaystyle{ x(t) }[/math], as a function of [math]\displaystyle{ t }[/math] to an output, [math]\displaystyle{ y(t) }[/math], a type of black box description. Linear systems satisfy the properties of superposition and scaling or homogeneity. Given two valid inputs  :[math]\displaystyle{ x_1(t) \, }[/math] :[math]\displaystyle{ x_2(t) \, }[/math] as well as their respective outputs :[math]\displaystyle{ y_1(t) = H \left \{ x_1(t) \right \} }[/math] :[math]\displaystyle{ y_2(t) = H \left \{ x_2(t) \right \} }[/math] then a linear system must satisfy :[math]\displaystyle{ \alpha y_1(t) + \beta y_2(t) = H \left \{ \alpha x_1(t) + \beta x_2(t) \right \} }[/math] for any scalar values [math]\displaystyle{ \alpha \, }[/math] and [math]\displaystyle{ \beta \, }[/math].

      The behavior of the resulting system subjected to a complex input can be described as a sum of responses to simpler inputs. In nonlinear systems, there is no such relation.

      This mathematical property makes the solution of modelling equations simpler than many nonlinear systems. For time-invariant systems this is the basis of the impulse response or the frequency response methods (see LTI system theory), which describe a general input function [math]\displaystyle{ x(t) }[/math] in terms of unit impulses or frequency components.

      Typical differential equations of linear time-invariant systems are well adapted to analysis using the Laplace transform in the continuous case, and the Z-transform in the discrete case (especially in computer implementations).

      Another perspective is that solutions to linear systems comprise a system of functions which act like vectors in the geometric sense.

      A common use of linear models is to describe a nonlinear system by linearization. This is usually done for mathematical convenience.