Projects
Please download all the projects from here: Projects
- Learning to Demap: Database Generation, Preprocessing, Postprocessing, Training, Validation and Inferences from the LLRNet
- Blockage Probability Analysis for RedCap Devices in 5G Networks
- Analysis of Blocking Probability for different Coverage Conditions
- Variation in Blocking Probability with Different Aggregation Levels (ALs)
- Analyzing the effect of Number of Candidates on Blocking Probability
- Analyzing the Impact of Scheduling Strategy on Blocking Probability
- Analyze the Impact of UE Capability on Blocking Probability
- Selection of minimum CORESET Size for a Given Target Block Probability
- Python Libraries
- 5G-Toolkit Libraries
- Simulation Parameters
- PDCCH Scheduling Parameters
- Compute minimum coreset size for
numUEs= 5. - Compute minimum coreset size for
numUEs= 10. - Compute minimum coreset size for
numUEs= 15. - Display Minimum CORESET size required to meet the Target Blocking Probability for different number of UEs.
- Artificial Intelligence and Machine Learning (AI-ML) for CSI Compression and Reconstruction in 5G Networks
- CSI Compression and Reconstruction using CSINet for TDD Massive MIMO 5G Networks
- Import Libraries
- Simulation Parameters
- Wireless Channel Generation: CDL-A
- Reconstrunction Performance of CSI-Net
- PDSCH Parameters
- PDSCH: Transmitter
- SVD Based Beamforming: Perfect CSI
- Pass through Channel
- Link Level Simulation: SVD based Beamforming using Perfect CSI
- SVD Based Beamforming: CSI Reconstructed using CSINet
- Pass through Wireless Channel
- Link Level Simulation: SVD based Beamforming using Imperfect CSI
- Performance Evaluations
- Wireless Channel Dataset Generation for Training the AI based Models
- Training the CSINet
- CSI Compression and Reconstruction using CSINet for TDD Massive MIMO 5G Networks
- Comparative Study of Reed Muller codes, Polar Codes and LDPC codes
- Link Level Simulations and Lnk budget Analysis for 5G Non Terrestrial Networks
- Coverage Evaluation of Physical Broadcast Channels (PBCH) in 5G Non-Terrestrial Networks
- Evaluation Methodology
- Import Python Libraries
- Import 5G Libraries
- Simulation Parameters
- Generate NTN Channel
- Generate MIB and PBCH Configurations for NTN
- PSS, SSS, PBCH, PBCH-DMRS and SSB Generation
- Transmission OFDM Resource Grid
- Pass through the Wireless Channel
- Heatmap of Received Grid
- Link Level Simulation: PBCH
- Displaying the Received Noisy Resource Grid
- Displaying Noisy SSB Grid
- Performance Evaluations: SNR vs BLER
- Link Level Simulation for Physical Downlink Control Channels in 5G Non-Terrestrial Networks (NTN)
- Link Level Simulation for Physical Downlink Shared Channel (PDSCH) in 5G Non Terrestrial Networks (NTN)
- Import Python Libraries
- Import 5G-Toolkit Libraries
- Simulation Parameters
- Generate Channel
- PDSCH Configurations
- PDSCH Implementation
- Pass through the Wireless Channel
- Recevier Side Processing
- Simulation Results: Reliability
- Simulation Results: Throughput
- Simulation Results: Reliability (Averaged over 32000 batches)
- Simulation Results: Throughput (Averaged over 32000 batches)
- Coverage Evaluation of Physical Broadcast Channels (PBCH) in 5G Non-Terrestrial Networks
- Hybrid Automatic repeat Request in 5G and Beyond
- Constellation Learning in an AWGN Channel
- Downlink Synchronization using SSB in 5G systems
- Uplink Synchronization using PRACH in 5G systems
- Performance comparison between different Positioning Methods for millimeter wave 5G Networks