The z-transform is a fundamental tool used in analyzing discrete-time systems, serving as the discrete-time counterpart of the Laplace transform. It aids in describing and analyzing various systems, particularly signals, alongside the discrete-time Fourier transform. Both the z-transform and the Laplace transform convert differential equations into algebraic equations, facilitating easier problem-solving. The z-transform turns a discrete-time signal into a series involving a complex variable, aiding analysis and problem-solving. This series allows each term to reflect a specific sampling instant of the signal. The z-transform converges only within its Region of Convergence (ROC), and understanding this region is crucial for analyzing system behavior and stability. The variable z is a complex number whose magnitude and phase are critical in system analysis. The unit circle in the z-plane, where the magnitude of z is one, helps assess stability and frequency response. A key property in z-transform analysis is the geometric series, which simplifies expressions and solutions. Understanding the z-transform and the ROC is essential for effective signal processing and control system applications.