Lectures:
Continuous-Time Signal w(t).
Basic Definitions. Time Averages. Orthogonal Functions. Sinusoidal Wave. Dirac Impulse.
Correlation Analysis of Continuous-Time Signal.
Spectral Analysis of Continuous-Time Signal I.
Fourier Series. Spectra. Energy Spectra. Power Spectra.
Spectral Analysis of Continuous-Time Signal II.
Fourier Transform. Spectral Density. Energy Spectral Density. Power Spectral Density.
Periodic Signal.
Correlation and Spectral Analysis of Periodic Signal.
Energy Signal.
Correlation and Spectral Analysis of Energy Signal.
Random Signal.
Correlation and Spectral Analysis of Random Signal. Random Process.
Signal and Noise.
Signal Distortion Caused by Noise. Selected Problems.
Review of Continuous-Time Linear Time-Invariant Lumped System I.
Linear System. Linear Time Invariant System. Convolution. Linear Time Invariant Lumped System. Description of the LTIL System by Ordinary Differential Equation.
Review of Continuous-Time Linear Time-Invariant Lumped System II.
Impulse Response. Transfer Function. Transformation of the Sinusoidal Wave by LTIL System. Stability Problem.
Discrete-Time Signal w[k].
Basic Definitions. Sinusoidal Wave. Kronecker's Delta Sequence. Sampling. Discrete-Time Signal w[k] Derivation from Continuous-Time Signal w(t). Correlation Analysis of Discrete-Time Signal.
Spectral Analysis of Discrete-Time Signal.
Discrete-Time Fourier Transform. Spectra. Energy Spectra. Power Spectra.
Spectral Density. Energy Spectral Density. Power Spectral Density.
Reconstruction of Continuous-Time Signal w(t) by w[k] Filtering.
Shannon's Theorem.
Review of Discrete-Time Linear Time-Invariant Lumped System.
Convolution. Description of the LTIL System by Ordinary Difference Equation.
Derivation of the Equation from Convolution. Impulse Response. Transfer Function. Stability Problem.
Projects:
Students projects are individual ones. Projects are oriented in Continuous Time Signal Correlation and Spectral Analysis. Student prepares an analysis of both the task and mathematic background, develops the method of the solution and the program in Matlab. The numerical results will explain by qualitative comment. Student will present his work by protocol of min. 2 and max. 4 pages, a program will be delivered at a discette.
Computer labs:
Use of MALTAB in the B.Sc. Course Signal Processing.
Laboratory Task Solution in MATLAB.
MATLAB Application Fundamentals I.
Individual Work of Student on PC in MATLAB: Basic MATLAB Operations.
Individual Work of Student on PC in MATLAB: Input and Output MATLAB Operations.
Laboratory Theme No. 1: Continuous Time Signal Correlation and Spectral Analysis.
Theme No. 1 Assignment
Laboratory Theme No. 1.
Discussion on the Task A.
Individual Work of Student on PC in MATLAB: Analysis of Sinusoidal Signal.
Task C Analysis of Periodic Signal
Discussion on the Task B
Individual Work of Student on PC in MATLAB: Analysis of Periodic Signal
Laboratory Theme No. 1.
Discussion on the Task C.
Individual Work of Student on PC in MATLAB: Analysis of Energy Signal.
Laboratory Theme No. 1.
Discussion on the Task D.
Individual Work of Student on PC in MATLAB: Analysis of Random Signal.
Tutorial Lesson on Laboratory Theme No. 1. Discussion on Final Results.
Individual Work of Student on PC in MATLAB: The Paper on Laboratory Theme No. 1 Compilation
MATLAB Toolbox SIMULINK Application Fundamentals. Laboratory Task Solution in MATLAB Toolbox SIMULINK
Individual Work of Student on PC in MATLAB: Basic MATLAB Toolbox SIMULINK Operations.
Final term for the submission of the Paper on Laboratory Theme No. 1.
Laboratory Theme No. 2: Continuous-Time Signal Filtering.
Theme No. 2 Assignment
Laboratory Theme No. 2.Discussion on the Task A
Individual Work of Student on PC in MATLAB SIMULINK: Systems of the first and second order. RC Low-Pass Filter Characteristics.
Laboratory Theme No. 2. Discussion on the Task B
Individual Work of Student on PC in MATLAB SIMULINK: Distortion of the signal by the system. Sinusoidal Signal Distortion Caused by a RC Filter.
Tutorial Lesson on Laboratory Theme No. 2. Discussion on Final Results. Individual Work of Student on PC in MATLAB: Laboratory Theme No. 2 Paper Compilation
Final term for the submission of the Paper on Laboratory Theme No. 2.
Tutorial Lesson on the Selected Problems of Signal Modulation.
The Course Conclusion
Continuous-Time Signal w(t).
Basic Definitions. Time Averages. Orthogonal Functions. Sinusoidal Wave. Dirac Impulse.
Correlation Analysis of Continuous-Time Signal.
Spectral Analysis of Continuous-Time Signal I.
Fourier Series. Spectra. Energy Spectra. Power Spectra.
Spectral Analysis of Continuous-Time Signal II.
Fourier Transform. Spectral Density. Energy Spectral Density. Power Spectral Density.
Periodic Signal.
Correlation and Spectral Analysis of Periodic Signal.
Energy Signal.
Correlation and Spectral Analysis of Energy Signal.
Random Signal.
Correlation and Spectral Analysis of Random Signal. Random Process.
Signal and Noise.
Signal Distortion Caused by Noise. Selected Problems.
Review of Continuous-Time Linear Time-Invariant Lumped System I.
Linear System. Linear Time Invariant System. Convolution. Linear Time Invariant Lumped System. Description of the LTIL System by Ordinary Differential Equation.
Review of Continuous-Time Linear Time-Invariant Lumped System II.
Impulse Response. Transfer Function. Transformation of the Sinusoidal Wave by LTIL System. Stability Problem.
Discrete-Time Signal w[k].
Basic Definitions. Sinusoidal Wave. Kronecker's Delta Sequence. Sampling. Discrete-Time Signal w[k] Derivation from Continuous-Time Signal w(t). Correlation Analysis of Discrete-Time Signal.
Spectral Analysis of Discrete-Time Signal.
Discrete-Time Fourier Transform. Spectra. Energy Spectra. Power Spectra.
Spectral Density. Energy Spectral Density. Power Spectral Density.
Reconstruction of Continuous-Time Signal w(t) by w[k] Filtering.
Shannon's Theorem.
Review of Discrete-Time Linear Time-Invariant Lumped System.
Convolution. Description of the LTIL System by Ordinary Difference Equation.
Derivation of the Equation from Convolution. Impulse Response. Transfer Function. Stability Problem.
Projects:
Students projects are individual ones. Projects are oriented in Continuous Time Signal Correlation and Spectral Analysis. Student prepares an analysis of both the task and mathematic background, develops the method of the solution and the program in Matlab. The numerical results will explain by qualitative comment. Student will present his work by protocol of min. 2 and max. 4 pages, a program will be delivered at a discette.
Computer labs:
Use of MALTAB in the B.Sc. Course Signal Processing.
Laboratory Task Solution in MATLAB.
MATLAB Application Fundamentals I.
Individual Work of Student on PC in MATLAB: Basic MATLAB Operations.
Individual Work of Student on PC in MATLAB: Input and Output MATLAB Operations.
Laboratory Theme No. 1: Continuous Time Signal Correlation and Spectral Analysis.
Theme No. 1 Assignment
Laboratory Theme No. 1.
Discussion on the Task A.
Individual Work of Student on PC in MATLAB: Analysis of Sinusoidal Signal.
Task C Analysis of Periodic Signal
Discussion on the Task B
Individual Work of Student on PC in MATLAB: Analysis of Periodic Signal
Laboratory Theme No. 1.
Discussion on the Task C.
Individual Work of Student on PC in MATLAB: Analysis of Energy Signal.
Laboratory Theme No. 1.
Discussion on the Task D.
Individual Work of Student on PC in MATLAB: Analysis of Random Signal.
Tutorial Lesson on Laboratory Theme No. 1. Discussion on Final Results.
Individual Work of Student on PC in MATLAB: The Paper on Laboratory Theme No. 1 Compilation
MATLAB Toolbox SIMULINK Application Fundamentals. Laboratory Task Solution in MATLAB Toolbox SIMULINK
Individual Work of Student on PC in MATLAB: Basic MATLAB Toolbox SIMULINK Operations.
Final term for the submission of the Paper on Laboratory Theme No. 1.
Laboratory Theme No. 2: Continuous-Time Signal Filtering.
Theme No. 2 Assignment
Laboratory Theme No. 2.Discussion on the Task A
Individual Work of Student on PC in MATLAB SIMULINK: Systems of the first and second order. RC Low-Pass Filter Characteristics.
Laboratory Theme No. 2. Discussion on the Task B
Individual Work of Student on PC in MATLAB SIMULINK: Distortion of the signal by the system. Sinusoidal Signal Distortion Caused by a RC Filter.
Tutorial Lesson on Laboratory Theme No. 2. Discussion on Final Results. Individual Work of Student on PC in MATLAB: Laboratory Theme No. 2 Paper Compilation
Final term for the submission of the Paper on Laboratory Theme No. 2.
Tutorial Lesson on the Selected Problems of Signal Modulation.
The Course Conclusion