Aldrin Ngorima

Student Type: PhD

Publications

2025

Ngorima, A. ., Helberg, A. ., & Davel, M. H. (2025). Simplified Temporal Convolutional-Based Channel Estimation for a WiFi Vehicular Communication Channel. IEEE 3rd Wireless Africa Conference (WAC). http://doi.org/10.1109/WAC63911.2025.10992609

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Simplified Temporal Convolutional-Based Channel Estimation for a WiFi Vehicular Communication Channel

@article{521,
  author = {Aldrin Ngorima and Albert Helberg and Marelie Davel},
  title = {Simplified Temporal Convolutional-Based Channel Estimation for a WiFi Vehicular Communication Channel},
  abstract = {},
  year = {2025},
  journal = {IEEE 3rd Wireless Africa Conference (WAC)},
  pages = {1 - 5},
  month = {02/2025},
  publisher = {IEEE},
  address = {Pretoria, South Africa},
  isbn = {979-8-3315-1758-8},
  doi = {10.1109/WAC63911.2025.10992609},
}

2024

Ngorima, A. ., Helberg, A. ., & Davel, M. H. (2024). Neural Network-Based Vehicular Channel Estimation Performance: Effect of Noise in the Training Set. Artificial Intelligence Research. SACAIR 2024. Communications in Computer and Information Science, vol 2326. http://doi.org/https://doi.org/10.1007/978-3-031-78255-8_12

Abstract BibTex Entry BibTeX Download PDF

view.pdf

Vehicular communication systems face significant challenges due to high mobility and rapidly changing environments, which affect the channel over which the signals travel. To address these challenges, neural network (NN)-based channel estimation methods have been suggested. These methods are primarily trained on high signal-to-noise ratio (SNR) with the assumption that training a NN in less noisy conditions can result in good generalisation. This study examines the effectiveness of training NN-based channel estimators on mixed SNR datasets compared to training solely on high SNR datasets, as seen in several related works. Estimators evaluated in this work include an architecture that uses convolutional layers and self-attention mechanisms; a method that employs temporal convolutional networks and data pilot-aided estimation; two methods that combine classical methods with multilayer perceptrons; and the current state-of-the-art model that combines Long-Short-Term Memory networks with data pilot-aided and temporal averaging methods as post processing. Our results indicate that using only high SNR data for training is not always optimal, and the SNR range in the training dataset should be treated as a hyperparameter that can be adjusted for better performance. This is illustrated by the better performance of some models in low SNR conditions when trained on the mixed SNR dataset, as opposed to when trained exclusively on high SNR data.

@article{516,
  author = {Aldrin Ngorima and Albert Helberg and Marelie Davel},
  title = {Neural Network-Based Vehicular Channel Estimation Performance: Effect of Noise in the Training Set},
  abstract = {Vehicular communication systems face significant challenges due to high mobility and rapidly changing environments, which affect the channel over which the signals travel. To address these challenges, neural network (NN)-based channel estimation methods have been suggested. These methods are primarily trained&nbsp;on high signal-to-noise ratio (SNR) with the assumption that training&nbsp;a NN in less noisy conditions can result in good generalisation.&nbsp;This study examines the effectiveness of training NN-based channel estimators on mixed SNR datasets compared to training solely on&nbsp;high SNR datasets, as seen in several related works. Estimators evaluated in this work include an architecture that uses convolutional layers and self-attention mechanisms; a method that employs temporal convolutional networks and data pilot-aided estimation; two methods that combine classical methods with multilayer perceptrons; and&nbsp;the current state-of-the-art model that combines Long-Short-Term Memory networks with data pilot-aided and temporal averaging methods&nbsp;as post processing. Our results indicate that using only high SNR&nbsp;data for training is not always optimal, and the SNR range in&nbsp;the training dataset should be treated as a hyperparameter that can&nbsp;be adjusted for better performance. This is illustrated by the better performance of some models in low SNR conditions when trained on&nbsp;the mixed SNR dataset, as opposed to when trained exclusively on&nbsp;high SNR data.},
  year = {2024},
  journal = {Artificial Intelligence Research. SACAIR 2024. Communications in Computer and Information Science},
  volume = {vol 2326},
  pages = {192 - 206},
  month = {12/2024},
  publisher = {Springer Nature Switzerland},
  address = {Cham},
  isbn = {978-3-031-78255-8},
  doi = {https://doi.org/10.1007/978-3-031-78255-8_12},
}

Ngorima, A. ., Helberg, A. ., & Davel, M. H. (2024). A Data Pilot-Aided Temporal Convolutional Network for Channel Estimation in IEEE 802.11p Vehicle-to-Vehicle Communications. Southern Africa Telecommunication Networks and Applications Conference (SATNAC).

Abstract BibTex Entry BibTeX Download PDF

2502.03246v1.pdf

In modern communication systems, having an accurate channel estimator is crucial. However, when there is mobility, it becomes difficult to estimate the channel and the pilot signals, which are used for channel estimation, become insufficient. In this paper, we introduce the use of Temporal
Convolutional Networks (TCNs) with data pilot-aided (DPA) channel estimation and temporal averaging (TA) to estimate vehicle-to-vehicle same direction with Wall (VTV-SDWW) channels. The TCN-DPA-TA estimator showed an improvement in Bit Error Rate (BER) performance of up to 1 order of magnitude. Furthermore, the BER performance of the TCN-DPA without TA also improved by up to 0.7 magnitude compared to the best classical estimator.

@article{515,
  author = {Aldrin Ngorima and Albert Helberg and Marelie Davel},
  title = {A Data Pilot-Aided Temporal Convolutional Network for Channel Estimation in IEEE 802.11p Vehicle-to-Vehicle Communications},
  abstract = {In modern communication systems, having an accurate channel estimator is crucial. However, when there is mobility, it becomes difficult to estimate the channel and the pilot signals, which are used for channel estimation, become insufficient. In this paper, we introduce the use of TemporalConvolutional Networks (TCNs) with data pilot-aided (DPA) channel estimation and temporal averaging (TA) to estimate vehicle-to-vehicle same direction with Wall (VTV-SDWW) channels. The TCN-DPA-TA estimator showed an improvement in Bit Error Rate (BER) performance of up to 1 order of magnitude. Furthermore, the BER performance of the TCN-DPA without TA also improved by up to 0.7 magnitude compared to the best classical estimator.},
  year = {2024},
  journal = {Southern Africa Telecommunication Networks and Applications Conference (SATNAC)},
  pages = {356–361},
}

2023

Ngorima, A. ., Helberg, A. ., & Davel, M. H. (2023). Sequence Based Deep Neural Networks for Channel Estimation in Vehicular Communication Systems. In Artificial Intelligence Research. SACAIR 2023. Communications in Computer and Information Science (Vol. 1976). Springer, Cham. http://doi.org/https://doi.org/10.1007/978-3-031-49002-6_12

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SACAIR_2023_paper_53 (3).pdf

Channel estimation is a critical component of vehicular communications systems, especially in high-mobility scenarios. The IEEE 802.11p standard uses preamble-based channel estimation, which is not sufficient in these situations. Recent work has proposed using deep neural networks for channel estimation in IEEE 802.11p. While these methods improved on earlier baselines they still can perform poorly, especially in very high mobility scenarios. This study proposes a novel approach that uses two independent LSTM cells in parallel and averages their outputs to update cell states. The proposed approach improves normalised mean square error, surpassing existing deep learning approaches in very high mobility scenarios.

@inbook{504,
  author = {Aldrin Ngorima and Albert Helberg and Marelie Davel},
  title = {Sequence Based Deep Neural Networks for Channel Estimation in Vehicular Communication Systems},
  abstract = {Channel estimation is a critical component of vehicular communications systems, especially in high-mobility scenarios. The IEEE 802.11p standard uses preamble-based channel estimation, which is not sufficient in these situations. Recent work has proposed using deep neural networks for channel estimation in IEEE 802.11p. While these methods improved on earlier baselines they still can perform poorly, especially in very high mobility scenarios. This study proposes a novel approach that uses two independent LSTM cells in parallel and averages their outputs to update cell states. The proposed approach improves normalised mean square error, surpassing existing deep learning approaches in very high mobility scenarios.},
  year = {2023},
  journal = {Artificial Intelligence Research. SACAIR 2023. Communications in Computer and Information Science},
  volume = {1976},
  pages = {176 - 186},
  month = {29 November 2023},
  publisher = {Springer, Cham},
  isbn = {978-3-031-49001-9},
  doi = {https://doi.org/10.1007/978-3-031-49002-6_12},
}