Opportunistic Large Array Propagation Models: A Comprehensive Survey
Abstract
:1. Introduction
2. Continuum Model with Deterministic Channel Assumption
3. One-Dimensional Propagation Models of OLA-Based Networks
3.1. Non-Overlapping 1D OLA Network
3.2. Overlapping 1D OLA Network
3.3. 1D OLA Network with Co-Locating Groups of Nodes
3.4. Randomly Deployed 1D OLA Network
4. Two-Dimensional Propagation Models of OLA-Based Networks
4.1. Overlapping 2D OLA Network
4.2. Non-Overlapping Fixed Boundary 2D OLA Network with a Fixed Number of Nodes at Arbitrary Locations
4.3. Non-Overlapping Fixed Boundary 2D OLA Network with a Random Number of Nodes with Arbitrary Locations
4.4. Large-Scale 2D OLA Network with Random Boundaries
5. Multi-Packet OLA Transmission Networks
5.1. 1D Multi-Packet OLA Network
5.2. 2D Multi-Packet OLA Network
5.3. 2D OLA Network with Multiple Sources
6. Energy-Efficient OLA Protocols
6.1. OLA with Transmission Threshold (OLA-T)
6.2. Alternating OLA-T (A-OLA-T)
6.3. OLA Concentric Routing Algorithm (OLACRA)
6.4. OLA Concentric Routing Algorithm with Threshold (OLACRA-T)
7. Future Directions
7.1. Scheduling in OLA Networks with Multiple Routes
7.2. OLA and Cooperative Routing for Underwater Sensor Networks
7.3. Machine Learning and Deep Learning-Based Relay Selections in OLA Cooperative Networks
7.4. Cooperation and Wireless-Powered Networks
7.5. Backscatter-Aided Cooperative Transmissions
7.6. Security for OLA Networks
8. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Conflicts of Interest
Abbreviations
5G | Fifth Generation |
B5G | Beyond Fifth Generation |
IoT | Internet-of-Things |
mMTC | massive machine-type communication |
CT | Cooperative Transmission |
OLA | Opportunistic Large Array |
IoT | Internet-of-Things |
mMTC | massive machine-type communication |
eMBB | enhanced mobile broadband |
D2D | Device-to-Device |
VMISO | Virtual Multiple-Input-Single-Output |
MISO | Multiple-Input-Single-Output |
SISO | Single-Input–Single-Output |
DF | Decode-and-Forward |
AF | Amplify-and-Forward |
MRC | Maximum Ratio Combining |
EGC | Equal Gain Combining |
SC | Selective Combining |
MAC | Medium Access Control |
1D | One-Dimensional |
2D | Two-Dimensional |
SDR | Software-Defined Radio |
SNR | Signal-to-Noise-Ratio |
PIR | Packet Insertion Rate |
UWSN | Underwater Sensor Network |
ML | Machine Learning |
DL | Deep learning |
BackCom | Backscatter Communication |
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Reference | Shape | Density | Node Locations | Set Boundary |
---|---|---|---|---|
[20] | Strip (2D) | Infinite | Fixed | Deterministic |
[14] | Disk (2D) | Infinite | Fixed | Deterministic |
[37] | Linear (1D) | Finite | Fixed | Non-overlapping |
[39] | Linear (1D) | Finite | Fixed | Overlapping |
[40] | Linear (1D) | Finite | Fixed (collocated) | Non-overlapping |
[41] | Linear (1D) | Finite | Random | Overlapping |
[42] | Strip (2D) | Finite | Fixed | Overlapping |
[43] | Strip (2D) | Finite | Random (fixed number) | Non-overlapping |
[44] | Strip (2D) | Finite | Random (random number) | Non-overlapping |
[45] | Strip (2D) | Finite | Random (random number) | Overlapping |
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Nawaz, F.; Kumar, H.; Hassan, S.A.; Jung, H. Opportunistic Large Array Propagation Models: A Comprehensive Survey. Sensors 2021, 21, 4206. https://doi.org/10.3390/s21124206
Nawaz F, Kumar H, Hassan SA, Jung H. Opportunistic Large Array Propagation Models: A Comprehensive Survey. Sensors. 2021; 21(12):4206. https://doi.org/10.3390/s21124206
Chicago/Turabian StyleNawaz, Farhan, Hemant Kumar, Syed Ali Hassan, and Haejoon Jung. 2021. "Opportunistic Large Array Propagation Models: A Comprehensive Survey" Sensors 21, no. 12: 4206. https://doi.org/10.3390/s21124206
APA StyleNawaz, F., Kumar, H., Hassan, S. A., & Jung, H. (2021). Opportunistic Large Array Propagation Models: A Comprehensive Survey. Sensors, 21(12), 4206. https://doi.org/10.3390/s21124206