Performance Evaluation of Cooperative OMA and NOMA Systems in 6G Deployment Scenarios
<p>System Model.</p> "> Figure 2
<p>Average sum rate for a different number of total users in the cell.</p> "> Figure 3
<p>Fairness factor of various schemes for a different number of total users in the cell.</p> "> Figure 4
<p>Average Energy Efficiency for a different number of total users in the cell.</p> ">
Abstract
:1. Introduction
2. Materials and Methods
2.1. Background of Research
2.2. Contributions
3. System Design
4. System Analysis
4.1. Sum Rate
4.2. Fairness Factor
4.3. Energy Efficiency
5. Performance Analysis
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Ref. No. | Algorithm Description | Parameters Optimized | Scenario | Type of Network |
---|---|---|---|---|
[13] | To study OMA, cooperative NOMA, and NOMA schemes and propose a scheme that maintains QoS for both near and far users. | Spectral Efficiency, Sum Rate, Energy Efficiency | Downlink | Two users |
[14] | According to CSI and the state of the buffer designed, the transmit power at each user to control inter-user interference and switch between the NOMA and OMA | Throughput, Outage probability, Delay | Uplink | Two users |
[15] | To enhance the sum rate by OMA and NOMA according to relay serving capabilities. Propose a buffer aided system to improve the outage probability. | Throughput, Outage probability, Delay | Downlink | Two users |
[12] | To enhance the energy efficiency, a NOMA network with a cooperative relay system is analyzed | Energy Efficiency | Downlink | Two users |
[16] | Analysis of the sum rate of MIMO-OMA and MIMO-NOMA systems | Sum rate | Downlink | Two users |
[18,19] | OMA and NOMA performance evaluation in the MIMO system | Capacity | Downlink | Multi-user |
[24] | OMA and NOMA latency evaluation with short-packet communications | Effective capacity | Downlink | Two-user |
[25] | Joint OMA and NOMA scheme for bandwidth efficiency | Throughput, Fairness | Downlink | Multi-user |
This Paper | In a practical scenario of non-uniform relay battery powers, a comparative evaluation of OMA and NOMA systems in three different deployment scenarios | Sum-rate,
System Energy Efficiency and System Fairness v/s number of users | Downlink | Multi-user |
Notation | Description |
---|---|
Number of users in the cell | |
Relay users set | |
Ğ | Cell-edge users set |
Number of relays | |
Total cell-edge users | |
User equipment battery power | |
relay | |
cell-edge user | |
Transmit power of BS | |
Maximum BS power | |
signal | |
link | |
for the signal transmitted by BS | |
cell-edge users | |
cell-edge users |
Parameters | Value |
---|---|
THz carrier frequency | 0.34 THz |
Bandwidth at BS employing THz channel | 10 GHz |
150 to 450 | |
Cell Radius for urban scenario | 500 m |
Cell Radius for sub-urban scenario | 1299 m |
Cell Radius for rural scenario | 1732 m |
42.7 dBm | |
Distance between BS and relay in an urban scenario | 300 to 400 m |
Distance between BS and cell-edge user in the urban scenario | 400 to 500 m |
Distance between BS and relay in sub-urban scenario | 900 to 1000 m |
Distance between BS and cell-edge in sub-urban scenario | 1000 to 1299 m |
Distance between BS and relay in the rural scenario | 1000 to 1300 m |
Distance between BS and cell-edge user in the rural scenario | 1300 to 1732 m |
Noise Power at the receiver of relay and cell-edge user, σ2, σm2 | −174 dBm/Hz |
−40 to 10 dBm | |
dB [25] |
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Jain, P.; Gupta, A.; Kumar, N.; Joshi, G.P.; Cho, W. Performance Evaluation of Cooperative OMA and NOMA Systems in 6G Deployment Scenarios. Sensors 2022, 22, 3986. https://doi.org/10.3390/s22113986
Jain P, Gupta A, Kumar N, Joshi GP, Cho W. Performance Evaluation of Cooperative OMA and NOMA Systems in 6G Deployment Scenarios. Sensors. 2022; 22(11):3986. https://doi.org/10.3390/s22113986
Chicago/Turabian StyleJain, Preksha, Akhil Gupta, Neeraj Kumar, Gyanendra Prasad Joshi, and Woong Cho. 2022. "Performance Evaluation of Cooperative OMA and NOMA Systems in 6G Deployment Scenarios" Sensors 22, no. 11: 3986. https://doi.org/10.3390/s22113986
APA StyleJain, P., Gupta, A., Kumar, N., Joshi, G. P., & Cho, W. (2022). Performance Evaluation of Cooperative OMA and NOMA Systems in 6G Deployment Scenarios. Sensors, 22(11), 3986. https://doi.org/10.3390/s22113986