This continuing module on Digital Filter Design focuses on advanced concepts and applications. Students will explore:
Through case studies and hands-on projects, students will enhance their understanding of digital filter applications.
This module covers the Discrete-Time Fourier Transform (DTFT), a fundamental tool in signal processing. Students will learn:
Through electronic whiteboard-based lectures, students will gain practical insights into working with DTFT.
This module continues the exploration of Digital Signal Processing, delving deeper into the concepts previously introduced. Key topics include:
Students are encouraged to apply theoretical knowledge in practical scenarios to enhance their understanding.
This module introduces the Fourier representation of signals, a critical concept for understanding signal behavior in the frequency domain. Students will explore:
Theoretical knowledge is paired with practical examples to solidify understanding.
This module provides an introduction to the Z-Transform, a powerful tool in analyzing discrete-time signals and systems. Key topics include:
Students will learn to apply the Z-Transform in various scenarios, enhancing their analytical skills.
This foundational module on Signals and Systems introduces students to the basic principles of how signals are generated and processed. Topics include:
Students will engage in practical exercises to reinforce theoretical concepts.
This module continues the exploration of Digital Signal Processing with additional advanced topics. Students will delve into:
Through interactive lectures, students will enhance their skills in applying these advanced concepts.
This module provides insights into the core principles of Digital Signal Processing, focusing on foundational concepts. Key areas of study include:
Students will learn to apply basic techniques to real-world scenarios, enhancing their understanding of digital signals.
This module focuses on Discrete-Time Systems, emphasizing the analysis and design of systems that process discrete signals. Students will explore:
Practical exercises will complement theoretical learning, allowing students to design effective discrete-time systems.
This module introduces Analogue Filter Design, a crucial aspect of signal processing. Students will learn:
Through interactive lectures and practical examples, students will gain hands-on experience in designing analogue filters.
This module on Digital Filter Design covers the essential techniques and methodologies for creating digital filters. Key topics include:
Students will engage in practical exercises, applying their knowledge to develop effective digital filters.
This continuing module on Digital Filter Design focuses on advanced concepts and applications. Students will explore:
Through case studies and hands-on projects, students will enhance their understanding of digital filter applications.
This module focuses on Multirate Digital Signal Processing, a vital area in contemporary signal processing. Key topics covered include:
Students will engage with practical examples to understand how multirate processing can improve system efficiency.