Kgaogelo Edwin Ramatsetse | Technology | Best Researcher Award

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Mr. Kgaogelo Edwin Ramatsetse | Technology | Best Researcher Award 

Lecturer, University of South Africa, South Africa

Kgaogelo Edwin Ramatsetse is a dedicated lecturer and food science researcher at the University of South Africa (UNISA), specializing in food safety and functional meat product innovation. With a passion for advancing nutritional science, he explores the use of indigenous African crops like Bambara groundnut and Moringa oleifera to enhance meat quality and public health outcomes. His interdisciplinary approach integrates food microbiology, product development, and preservation technologies. Recognized as the Best Graduand in Food Science and Technology at the University of Venda, Ramatsetse continues to mentor students, collaborate with research teams, and publish impactful scientific articles that contribute to both academic advancement and industry transformation.

Professional Profile

Google Scholar

🎓 Education

Ramatsetse holds a Master of Science (MSc) in Food Science and Technology from the University of Venda. His academic training focused on bioprocessing, nutritional analysis, quality assurance, and food preservation. This solid foundation has guided his professional path as an educator and researcher.

💼 Experience

Ramatsetse’s career journey spans academia, government research, and the private sector. He served as a Research and Innovation Intern at the University of Venda, a Laboratory Assistant, and later interned at the Agricultural Research Council. He also gained industry exposure at Cavalier Foods. Currently, as a lecturer at UNISA, he leads research initiatives, mentors undergraduate and postgraduate students, and contributes to academic development through publications and conferences.

🔬 Research Interests

His primary research interests include food safety, meat science, nutritional enhancement through functional ingredients, and the valorization of underutilized crops. He is particularly interested in the microbiological safety of meat products and how plant-based fortification can improve shelf life, sensory attributes, and health benefits. Ramatsetse is also developing a PhD proposal focusing on meat safety, microbial hazards, and regulatory frameworks.

📚Publications Top Notes

“Effects of Adding Moringa oleifera Leaves Powder on the Nutritional Properties, Lipid Oxidation and Microbial Growth in Ground Beef during Cold Storage”
Authors: Mashau ME, Ramatsetse KE, Ramashia SE
Journal: Applied Sciences, Vol. 11(7), Article 2944 (2021)
Citations: 44
Summary: This experimental study demonstrated that incorporating Moringa oleifera powder into ground beef significantly improved its antioxidant stability, delayed lipid oxidation, and inhibited microbial growth during refrigeration. The findings support the use of natural plant additives for extending the shelf life and enhancing the nutritional profile of meat products.

“A Review on Health Benefits, Antimicrobial and Antioxidant Properties of Bambara Groundnut (Vigna subterranea)”
Authors: Ramatsetse KE, Ramashia SE, Mashau ME
Journal: International Journal of Food Properties, Vol. 26(1), pp. 91–107 (2023)
Citations: 39
Summary: This comprehensive review compiled existing research on the health-promoting properties of Bambara groundnut, highlighting its high protein content, bioactive compounds, and potential as a sustainable functional ingredient. The paper emphasized its antioxidant and antimicrobial capabilities, encouraging its use in food systems, especially meat formulations.

“Impact of Industrial Revolutions on Food Machinery – An Overview”
Authors: Jideani AIO, Mutshinyani AP, Maluleke NP, Mafukata ZP, Sithole MV, et al. (incl. Ramatsetse KE)
Journal: Journal of Food Research, Vol. 9(5), pp. 42–52 (2020)
Citations: 27
Summary: This article reviewed the evolution of food processing machinery across industrial revolutions, discussing advancements in automation, digitalization, and intelligent systems. Ramatsetse’s contribution helped assess how modern machinery can improve food safety, quality, and efficiency in production.

“The Incorporation of Moringa oleifera Leaves Powder in Mutton Patties: Influence on Nutritional Value, Technological Quality, and Sensory Acceptability”
Authors: Khomola GT, Ramatsetse KE, Ramashia SE, Mashau ME
Journal: Open Agriculture, Vol. 6(1), pp. 738–748 (2021)
Citations: 10
Summary: This study assessed the effects of adding Moringa leaf powder to mutton patties. It showed improvements in protein and fiber content, while enhancing water-holding capacity and maintaining consumer acceptability. The research validates the role of Moringa in creating healthier, functional meat products.

“Effect of Partial Mutton Meat Substitution with Bambara Groundnut (Vigna subterranea (L.) Verdc.) Flour on Physicochemical Properties, Lipid Oxidation, and Sensory Attributes”
Authors: Ramatsetse KE, Ramashia SE, Mashau ME
Journal: Food Science & Nutrition, Vol. 12(6), pp. 4019–4037 (2024)
Citations: 6
Summary: This recent article explored replacing mutton with Bambara groundnut flour in patties. The results showed improved moisture retention and antioxidant capacity, while reducing saturated fat content. It also maintained favorable taste and texture, supporting plant-based meat innovation.

🏅 Conclusion

Kgaogelo Edwin Ramatsetse is a promising researcher whose academic achievements and published work are already contributing to food safety, public health, and sustainable innovation in meat science. His research addresses timely challenges in nutrition and food preservation, using African resources to find global solutions. With a total of 8 journal publications, a citation index of 4, and several high-impact articles, he continues to expand his influence in both academic and applied food science. His commitment to student mentorship, multidisciplinary collaboration, and research dissemination makes him a strong candidate for the Best Researcher Award.

Mingyue Cui | Computer Science and Technology | Best Researcher Award

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Mr. Mingyue Cui | Computer Science and Technology | Best Researcher Award

Dr. Mingyue Cui is a pioneering computer scientist whose multidisciplinary work bridges intelligent vehicles, biomedical computing, and real-time embedded systems. He earned his Ph.D. in Computer Science and Engineering from Sun Yat-sen University, with research affiliations at the Technical University of Munich. His scholarly journey reflects deep engagement in applied AI, autonomous driving, edge computing, and sensor data processing. Dr. Cui has authored over 20 high-impact papers in IEEE and AAAI venues and holds several national patents in autonomous systems and LiDAR compression. His innovation has been recognized through prestigious awards, including top honors in robotics and AI design competitions in China. Dr. Cui continues to advance research in scalable, low-cost AI for smart healthcare and mobility, driving collaborations across academia and industry.

Profiles

Google Scholar

Scopus

🎓 Education

Mingyue Cui holds a Ph.D. in Computer Science and Engineering from Sun Yat-sen University (2018–2022), with research conducted in partnership with the Technical University of Munich. His doctoral work, supervised by Prof. Kai Huang, focused on intelligent connected vehicles, emphasizing autonomous driving systems and biomedical signal processing. Prior to this, he completed a Master’s degree in Software Engineering (2015–2017) from the same university, authoring a thesis on real-time scene flow for embedded systems. His Bachelor’s degree in Software Engineering (2010–2014) was obtained from Chongqing Normal University, where he specialized in embedded software engineering. His academic training spans advanced topics like optimization theory, computational complexity, machine learning, and embedded systems.

🧪 Experience

Dr. Mingyue Cui has built a robust research profile with a focus on real-world applications of AI and embedded systems. His Ph.D. thesis explored intelligent connected vehicles, targeting the challenges of real-time computation and network reliability in autonomous driving. He led pioneering efforts in algorithm parallelization, edge computing for autonomous services, and quality of service assurance using low-cost embedded platforms. His current research has expanded to biomedical domains, particularly ECG signal processing and cardiovascular disease diagnostics. With over 20 academic publications and patents, Cui collaborates extensively with Prof. Kai Huang and research groups at both Sun Yat-sen University and the Technical University of Munich. In addition to his academic output, he actively contributes to competitive research through international robotics and AI competitions, where he has earned multiple first and second-place awards.

🏆 Awards and Honors 

Dr. Mingyue Cui’s research excellence is widely recognized through multiple awards. In 2023, he received a Bronze Award at the China College Students’ ‘Internet+’ Innovation Competition. He also secured the First Prize at the CCF Mobile Robot Challenge with a $10,000 grant, and a Second Prize in the International Running Intelligent Robot Competition. Earlier, he won the First Prize in the same international robotics event in 2019. In 2021, he earned the Second Prize in the World 5G Conference Application Design Competition. These accolades highlight his ability to translate complex theoretical work into high-impact innovations, especially in robotics, autonomous systems, and AI-powered design.

🔍 Research Focus 

Dr. Mingyue Cui’s research integrates real-time embedded systems, AI-driven autonomous vehicles, biomedical signal processing, and point cloud compression. His Ph.D. centered on Intelligent Connected Vehicles (ICV), where he developed methods for optimizing service offloading and computing efficiency while maintaining Quality of Service under network fluctuations. His recent research includes developing hybrid CNN-Transformer models for ECG denoising, distributed AI processors for seizure detection, and octree-based transformers for LiDAR compression. With applications spanning autonomous mobility to wearable health diagnostics, Cui’s work emphasizes scalable, cost-effective, and intelligent system architectures. He is also deeply involved in collaborative SLAM for multi-vehicle networks and cross-modal sensor fusion, pushing the boundaries of edge computing in real-time robotics and healthcare contexts.

📄 Publication Top Notes

1. Dense Depth-Map Estimation Based on Fusion of Event Camera and Sparse LiDAR

Cui et al., IEEE Transactions on Instrumentation and Measurement, 2022
This paper presents a novel method combining sparse LiDAR data with asynchronous event camera signals to estimate dense depth maps efficiently. The fusion approach leverages temporal resolution from event cameras and spatial accuracy from LiDAR to improve performance in dynamic environments.

2. Offloading Autonomous Driving Services via Edge Computing

Cui et al., IEEE Internet of Things Journal, 2020
A seminal work on optimizing the offloading of AI services in autonomous driving. It explores real-time system performance under various load conditions and proposes an adaptive framework to ensure service continuity with minimal latency.

3. OctFormer: Efficient Octree-Based Transformer for Point Cloud Compression

Cui et al., AAAI Conference on Artificial Intelligence, 2023
Proposes OctFormer, an efficient transformer architecture for compressing point cloud data using octree structures. It achieves local detail preservation with high compression ratios, enabling faster data transmission in autonomous systems.

4. OctFormer: Efficient Octree-Based Transformer for Point Cloud Compression

Cui et al., AAAI 2023
This paper introduces OctFormer, a novel transformer-based framework that leverages the octree structure for efficient point cloud compression. It enhances local feature extraction while achieving significant compression gains, facilitating faster 3D data transfer in autonomous systems.

5. ECG Signal Denoising Based on Hybrid CNN-Transformer Network

Cui et al., Journal of Healthcare Engineering, 2023
This study proposes a deep hybrid model combining Convolutional Neural Networks (CNNs) and Transformers to denoise ECG signals. The model effectively suppresses motion artifacts and improves diagnostic signal quality, contributing to wearable and mobile health solutions.

6. Distributed Lightweight AI Processor for Real-Time Epileptic Seizure Detection

Cui et al., Biomedical Signal Processing and Control, 2022
Presents a low-latency, power-efficient edge processor design for seizure detection using EEG signals. The AI model is optimized for resource-constrained devices, enabling early and accurate detection in remote or wearable healthcare settings.

7. Cooperative SLAM for Multi-Vehicle Systems Based on Dynamic Bayesian Optimization

Cui et al., IEEE Access, 2021
This paper addresses collaborative simultaneous localization and mapping (SLAM) for autonomous vehicles. It proposes a Bayesian optimization strategy to dynamically adjust SLAM parameters across a vehicle fleet, enhancing map accuracy and robustness in changing environments.

8. Quality of Service-Oriented Computation Offloading for Autonomous Driving Applications

Cui et al., Sensors, 2020
Focuses on computation offloading strategies that prioritize QoS in vehicle-to-edge communication. It balances task latency and network reliability to ensure real-time performance for self-driving applications, even under fluctuating network conditions.

9. Real-Time Scene Flow Estimation for Stereo Vision Using Embedded GPU Platforms

Cui et al., International Conference on Embedded Systems and Applications, 2019
Develops a lightweight algorithm for estimating scene flow from stereo images, optimized for embedded GPU platforms. The approach supports real-time performance, enabling practical deployment in mobile robots and AR/VR applications.

10. LiDAR-Assisted Pedestrian Detection Based on Multi-Sensor Fusion with Deep Learning

Cui et al., Proceedings of the Chinese Conference on Intelligent Transportation, 2021
Integrates LiDAR data with camera input using a deep fusion network to enhance pedestrian detection accuracy in autonomous vehicles. The fusion technique improves robustness in low-light or occluded conditions.

Conclusion

Dr. M. Cui is a highly accomplished and forward-thinking researcher with:

  • A clear impact in autonomous systems and intelligent robotics,

  • Strong innovation credentials (patents and real-world applications),

  • Recognized technical contributions through competitive awards, and

  • A trajectory that continues to expand into biomedical applications.

He is highly suitable for a Best Researcher Award, especially in fields related to smart mobility, embedded systems, and AI-powered healthcare technologies.