Please read project description if you can do it let me know..
joint channel and impulse noise estimation using compressive sensing for power line communication with adaptive guard interval length.
The project will be performed in matlab environment. I will design a communication system. The system will use OFDM modulation scheme at transmitter side, where each subcarrier in OFDM will be BPSK modulated. After the transmitter a powerline channel (narrow band) will be used, impulse noise is also added to the transmitted signal along with colored guassian noise. at receiver side, channel estimation and equalization will be performed. my task is to perform channel and impulse noise estimation using compressive sensing (using spgl1 algorithm) and compare the results with conventional channel estimation techniques like LS, MMSE etc on the basis of their bit error rates. also I have to make the guard interval length in ofdm adaptive and each time after doing the channel estimation, feed the information back to the transmitter to adjust the guard interval length to the changing channel conditions (i.e. if channel impulse response is larger as compared to guard interval length then increase the guard interval length and vice versa). the estimated noise will be subtracted from the received signal. the resulting responses will be plotted in the form, bit error rate Vs received signal to noise ratio.
MATLAB ASSIGNMENTS COMPLETED
NAVIGATION ASSIGNMENTS
1. 3D Great Circle path generation from one location on Earth to another.
SPACE FLIGHT MECHANICS ASSIGNMENTS
1. Computation of Right ascension and declination angle of Sun for an entire year
2. Transfer orbit generation of a satellite from Low earth orbit to Geostationary orbit
3. Determination of Ground based antenna angles for tracking any satellite
4. Determination of Antenna azimuth and elevation gimbal rates required to track any satellite
5. Orbit determination of Satellite in 3D ECI frame.
CONTROL THEORY ASSIGNMENTS COMPLETED
1. PD control of Deployment Rates
2. Response of a Flexible Satellite
3. Rate controller with two integral gains
4. Tracking Error of a Launch Vehicle
5. Steady-state pitch error of LV with the integral gain
6. Relationship of Kv with poles and zeros
7. Lead compensation for settling on a target
8. Root Locus of Helicopter Control
9. Antenna Azimuth Control with a Lead-Lag Compensator