19.5:
Inverse z-Transform by Partial Fraction Expansion
The inverse Z-transform is an essential tool used for converting a function from its frequency domain representation back to the time domain.
Consider the function X(z), which needs to be converted back to its time-domain representation.
To decompose X(z), the poles of the function are identified, and it is expressed in terms of these poles.
Each pole contributes a term to the partial fraction expansion.
The coefficients for each term in the expansion are determined by substituting specific values for z.
After determining all the coefficients, the function is reassembled in its decomposed form.
This new representation is more manageable.
Each fraction corresponds to known Z-transform pairs, making the inverse transformation simple.
The partial Fraction Method is an effective technique for finding the inverse Z-transform by decomposing a function into simpler fractions with distinct coefficients.
The inverse Z-transform is applied to each fractional term separately, resulting in a combination of delta functions, exponential sequences, and step functions, collectively representing the original time-domain sequence.
19.5:
Inverse z-Transform by Partial Fraction Expansion
The inverse z-transform is a crucial technique for converting a function from its z-domain representation back to the time domain. One effective method for finding the inverse z-transform is the Partial Fraction Method, which involves decomposing a function into simpler fractions with distinct coefficients. These fractions correspond to known z-transform pairs, facilitating the inverse transformation process.
To begin the process, the poles of the function are identified and the function is expressed in terms of these poles. Each pole contributes a term to the partial fraction decomposition. The coefficients for each term in the decomposition are determined by evaluating the residues at each pole.
Once the coefficients are determined, the function is reassembled in its decomposed form, making it simpler to work with. The inverse z-transform is then applied to each fractional term separately. The result combines delta functions, exponential sequences, and step functions representing the original time-domain sequence.
Using the Partial Fraction Method, the inverse z-transform of complex functions becomes more manageable, allowing for accurate conversion back to the time domain. This method ensures that each component of the decomposed function is correctly transformed, resulting in a precise reconstruction of the original sequence.