Reliable Aerial Mobile Communications with RSRP & RSRQ Prediction Models for the Internet of Drones: A Machine Learning Approach
Abstract
:1. Introduction
- A comprehensive measurement campaign has been conducted in a 4G LTE network within a suburban environment, consisting of about 28,000 physical layer samples. The performed aerial drive test focused on mobile link reliability between UAV and terrestrial BS. Hence, parameters such as RSRP, RSRQ, latency, and handover were measured.
- An open-source dataset has been provided, which is publicly accessible at [18]. The dataset contains about six hours of aerial drive tests under different measurement scenarios such as routes, BS, BSs’ heights, and UAV’s height in a harsh tropical suburban environment.
- Performance of the cellular-connected UAV system in the commercial LTE network has been investigated in a 3D form, under different distances and flight heights, in terms of RSRP and RSRQ. The statistical analysis reveals the performance of terrestrial BS in providing aerial coverage under different distances and flight heights. The output of this stage can be extended for other UAV mobile connectivity research, such as UAV path planning optimization.
- Six ML-based models have been considered and evaluated for an accurate RSRP and RSRQ prediction for LTE networks in suburban environments. Multiple linear regression, polynomial, and logarithmic methods were utilized to estimate the level of RSRP and RSRQ based on the 2D distance between the drone and serving BS, elevation angle, and flight height.
2. Related Works
3. Methodology
3.1. Field Trial Measurement
3.2. ML-Based RSRP and RSRQ Prediction Models
4. Results and Discussion
4.1. Measurement Results and Analysis
4.2. RSRP and RSRQ Prediction Models
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Ref. | Study Focus | Modeling Approach | Key Findings/Contributions | Limitations |
---|---|---|---|---|
[13,15,20,21] | Performance evaluation of cellular-connected drones | N/A | Demonstrated how drones are served by BS antenna sidelobes and revealed the issue of HO when drones move to the BS antenna sidelobe nulls. | Simulation-based and do not fully reflect real-world technical challenges and constraints. |
[12,22,23] | N/A | The evaluation was based on field measurements. Showed that existing 4G LTE networks could provide communication links for low-altitude drones. | The evaluations were limited to specific communication scenarios, such as remote or rural environments. | |
[24] | Investigate LTE performance for UAV | N/A | Found that the existing LTE network can provide aerial coverage, constrained to the position of the UAV to the serving BS. | Limited to performance evaluation in suburban environments. |
[25] | Survey existing and recently developed channel models | N/A | Reviewed recent state-of-the-art air-to-ground channel models for different technologies, including cellular-connected UAVs. | Limited to surveying existing models and recent developments for channel modeling. |
[26] | UAV-to-BS channel modeling | Empirical path loss modeling for UAV-to-BS scenario. | The path loss exponents decrease by increasing the flight height, approximating free space propagation. | Limited to certain communication scenarios, utilizing conventional modeling techniques. |
[27] | Statistical path loss modeling UAV-to-BS scenario. | The proposed path loss model is a function of the depression angle and the terrestrial coverage beneath the UAV. | Limited for suburban environments. | |
[28] | UAV-to-BS RSS modeling | ML-based modeling for RSS prediction. | - | The proposed method was simply a distance function, neglecting the effect of parameters such as the UAV’s height or elevation angle. |
[29] | UAV-to-BS RSS modeling | ML-based (ensemble) modeling for RSS or RSRP prediction. Using nine input features. | They have utilized multiple ensemble learning methods to predict the RSS at several heights and presented a new ensemble method based on five base learners. | Limited to RSS prediction and uses latitude and longitude as input features to the models, making it a site-specific model. |
[30] | UAV-to-BS RSRP modeling | ANN for RSRP prediction | Developed two hybrid training methods, the jDE and the CoDE algorithms. Both methods showed favorable outcomes, with CoDE-LM achieving the best. | Uses latitude and longitude as input features, making the proposed model site-specific. |
[31] | UAV-to-BS RSRP and RSRQ modeling | Deep ANN for RSRP and RSRQ prediction. | Results showed that the model performed decently with a cost function of 0.3 dB for training data and 0.4dB for validation data when predicting RSRP. | Limited to one BS in a rural environment, lacking other communication scenarios and using limited training/testing datasets. Uses latitude and longitude as input features, making the proposed model site-specific. |
Type of BS | No. of Sectors | Tilt Angle (Degree) | Height (m) Above Ground Level | Height (m) Above Sea Level | |
---|---|---|---|---|---|
BS A | Tower located on a hill | 3 × 120° | 6 | 28 | 99 |
BS B | Rooftop | 3 × 120° | 4 | 11 | 72 |
BS C | Rooftop | 3 × 120° | 4 | 23 | 56 |
BS D | Rooftop | 3 × 120° | 4 | 12 | 46 |
Signal Strength/Quality | RSRP | RSRQ |
---|---|---|
Excellent | −60~−70 dBm | >−6 dB |
Good | −70~−80 dBm | −6~−10 dB |
Medium | −80~−90 dBm | −10~−15 dB |
Weak | −90~−100 dBm | <−15 dB |
Distance (m) | Elevation Angle (Degree) | Height (m) | RSRP (dBm) | RSRQ (dB) | |
---|---|---|---|---|---|
mean | 242.195 | 24.534 | 79.547 | −74.735 | −11.396 |
std | 141.782 | 17.066 | 28.396 | 5.832 | 3.081 |
min | 10.534 | 0.560 | 6.000 | −98.000 | −20.000 |
25% | 140.183 | 13.090 | 59.000 | −79.000 | −14.000 |
50% | 224.761 | 21.040 | 89.000 | −75.000 | −11.000 |
75% | 322.479 | 30.520 | 99.000 | −71.000 | −9.000 |
max | 1045.209 | 82.700 | 119.000 | −59.000 | −5.000 |
Proposed Method/Reference | RMSE | MAPE (%) | MedAE | Notes |
---|---|---|---|---|
LARS Lasso | 4.58 | 4.9 | 3.04 | - |
SVR | 4.60 | 5.0 | 2.99 | - |
Polynomial | 4.49 | 4.8 | 2.90 | - |
Logarithmic | 4.37 | 4.6 | 2.81 | - |
[31] | 6.26 | 3.92 | - | Predicts RSS |
[32] | 6.674 | 3.357 | - | - |
[33] | 9.63–12.32 | - | - | - |
Method | RMSE | MAPE (%) | MedAE |
---|---|---|---|
LARS Lasso | 2.80 | 22 | 1.86 |
SVR | 2.81 | 21 | 1.86 |
Polynomial | 2.75 | 22 | 1.90 |
Logarithmic | 2.71 | 21 | 1.87 |
Polynomial Degree | RMSE | MAPE (%) | MedAE |
---|---|---|---|
2 | 4.49 | 4.8 | 2.90 |
4 | 4.33 | 4.6 | 2.82 |
6 | 4.31 | 4.6 | 2.80 |
8 | 4.39 | 4.7 | 2.84 |
10 | 4.48 | 4.8 | 2.97 |
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Behjati, M.; Zulkifley, M.A.; Alobaidy, H.A.H.; Nordin, R.; Abdullah, N.F. Reliable Aerial Mobile Communications with RSRP & RSRQ Prediction Models for the Internet of Drones: A Machine Learning Approach. Sensors 2022, 22, 5522. https://doi.org/10.3390/s22155522
Behjati M, Zulkifley MA, Alobaidy HAH, Nordin R, Abdullah NF. Reliable Aerial Mobile Communications with RSRP & RSRQ Prediction Models for the Internet of Drones: A Machine Learning Approach. Sensors. 2022; 22(15):5522. https://doi.org/10.3390/s22155522
Chicago/Turabian StyleBehjati, Mehran, Muhammad Aidiel Zulkifley, Haider A. H. Alobaidy, Rosdiadee Nordin, and Nor Fadzilah Abdullah. 2022. "Reliable Aerial Mobile Communications with RSRP & RSRQ Prediction Models for the Internet of Drones: A Machine Learning Approach" Sensors 22, no. 15: 5522. https://doi.org/10.3390/s22155522
APA StyleBehjati, M., Zulkifley, M. A., Alobaidy, H. A. H., Nordin, R., & Abdullah, N. F. (2022). Reliable Aerial Mobile Communications with RSRP & RSRQ Prediction Models for the Internet of Drones: A Machine Learning Approach. Sensors, 22(15), 5522. https://doi.org/10.3390/s22155522