Linear Time Invarient System: Difference between revisions

Latest revision as of 17:08, 5 November 2006

Signals and Systems

LTI systems

LTI System theory is a powerful and widely used concept in electrical engineering. It has applictions in circuit anlysis, control theory , and our main topic of interest signal processing.

LTI system properties

A system is considered to be a Linear Time Invariant when it satisfies the two basic criteria implied in its name, one it must be linear and two it must be time invariant. A Linear system is characterized by two properties superposition (additivity) and scaling (homogeneity). The superposition principal says that for any linear system a linear combination of solutions to the system is also a solution to the same linear system. The principal of scaling implies that if you adjust your scale an input by N amount, your output will also be adjusted by N amount. An example of a linear system then would be,

x_{1} (t)

x_{2} (t)

y_{1} (t) = H (x_{1} (t))

y_{2} (t) = H (x_{2} (t))

A y_{1} (t) + B y_{2} (t) = H (A x_{2} (t) + B x_{1} (t))

for any scalar values of A and B.

Time invariance of a system means that if any input $x (t)$ is shifted by some amount of time T the out-put will also be adjusted by that amount of time. This implies that for,

H (x (t)) = y (t)

H (x (t - T)) = y (t - T)

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+*[[Signals and systems|Signals and Systems]]
 ==LTI systems==
 LTI System theory is a powerful and widely used concept in electrical engineering.  It has applictions in circuit anlysis, control theory , and our main topic of interest signal processing.
 ===LTI system properties===
-A system is considered to be a Linear Time Invarient when it satifies the two basic criteria implied in its name, one it must be linear and two it must be time invarient.  A Linear system is charterized by two propeties superposition (additvity) and scaling (homegeneity).  The superpostion principal says that for any linear system a linear combination of solutions to the system is also a solution to the same linear system.   The principal of scaling implies that if you adjust your scale an input by N amount, your output will also be adjusted by N amount.  An example of a Linear system then would be,
+A system is considered to be a Linear Time Invariant when it satisfies the two basic criteria implied in its name, one it must be linear and two it must be time invariant.  A Linear system is characterized by two properties superposition (additivity) and scaling (homogeneity).  The superposition principal says that for any linear system a linear combination of solutions to the system is also a solution to the same linear system.   The principal of scaling implies that if you adjust your scale an input by N amount, your output will also be adjusted by N amount.  An example of a linear system then would be,
-::<math>x_1(t)</math>
+::<math>x_1(t)\!</math>
-::<math>x_2(t)</math>
+::<math>x_2(t)\!</math>
-::<math>y_1(t) = H(x_1(t))</math>
+::<math>y_1(t) = H(x_1(t))\!</math>
-::<math>y_2(t) = H(x_2(t))</math>
+::<math>y_2(t) = H(x_2(t))\!</math>
-::<math>Ay_1(t) + By_2(t) = H(Ax_2(t) + Bx_1(t))</math>
+::<math>Ay_1(t) + By_2(t) = H(Ax_2(t) + Bx_1(t))\!</math>
 for any scalar values of A and B.
-Time invarience of a system means that for adjust any input <math>x(t)</math> by some amout of time T the out put will also be adjusted by that amount of time.  This impies that for,
+Time invariance of a system means that if any input <math>x(t)</math> is shifted by some amount of time T the out-put will also be adjusted by that amount of time.  This implies that for,
-::<math>x(t - T)</math>
+::<math>H(x(t))=y(t)\!</math>
-::<math>y(t - T) = H(x(t - T))</math>
+::<math>H(x(t - T))=y(t-T)\!</math>
+<br>
+<br>
+Related Links
+*[[The Game]]

Linear Time Invarient System: Difference between revisions

Latest revision as of 17:08, 5 November 2006

LTI systems

LTI system properties

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