Exp 1: Plot BER curves for BPSK, QPSK and higher modulation schemes for the AWGN, flat fading and Rayleigh fading channels.
Compare the simulated and theoretical curves.

Exp 2: Plot BER curves for Receiver diversity in the Rayleigh fading channel using SC, EGC and MRC techniques.

Exp 3: Simulate a MIMO input using singular value decomposition for zero coefficients.

Exp 4: Simulate optimum power allocation in a MIMO system using a Water filling algorithm.

Exp 5: Design and simulate an OFDM communication system using MATLAB and plot the BER in AWGN and Rayleigh fading channels.

Exp 6: Design and simulate a CDMA system using orthogonal codes and plot the BER in AWGN and Rayleigh fading channels.

Exp 7: Design and simulate a CDMA system using non-orthogonal codes and plot the BER in AWGN and Rayleigh fading channels.

Exp 8: Design and simulate an FHMA system using 10 different carrier frequencies and plot the BER in AWGN and Rayleigh fading channels.

Exp 9: Design a MIMO system using STBC in MATLAB.

Exp 10: Simulate a V-BLAST system using MATLAB.

Design and testing of the performance of various modulation schemes in different
wireless channel models.

Design of diversity and equalization techniques for wireless applications.

Study of MIMO systems with various modulation and coding schemes.

Analysis of multicarrier modulation techniques.
Design and application of various spread spectrum modulation schemes.

CO1: To get well versed with the use of different modulation techniques.
CO2: To be able to model and analyze the wireless channels.
CO3: To learn to apply the schemes to improve the quality of received signals.
CO4: To learn the methodology to model MIMO, OFDM and MIMO-OFDM systems.
CO5: To study and analyze the MIMO system with STBC coding.

WH Tranter, TS Rappaport, KL Kosbar, KS Shanmugan, Principles of Communication Systems Simulation with Wireless Applications, Prentice Hall, 2004