Tran Manh Hoang | UAV, SPC | Best Researcher Award

Tran Manh Hoang | UAV, SPC | Best Researcher Award

 Dr Tran Manh Hoang Radio department , Vietnam

He is received the B.S. degree in Communication Command at Telecommunications University, Ministry of Defense, Vietnam, in 2002, and the B.Eng. degree in Electrical Engineering from Le Quy Don Technical University, Ha Noi, Vietnam, in 2006. He obtained the M.Eng. degree in Electronics Engineering from Posts and Telecommunications, Institute of Technology, (VNPT), Vietnam, in 2013. He is received the Ph.D degree at Le Quy Don Technical University, Hanoi, Vietnam in 2018. His research interests include energy harvesting, Non-orthogonal Multiple Access, MIMO, and signal processing for wireless cooperative communications.

Education:

The Telecommunications University in Nha Trang, Vietnam, stands as a beacon of academic excellence in the field of telecommunications. Renowned for its commitment to cutting-edge technology and innovative education, this institution has become a key player in shaping the future of communication systems. Nestled in the picturesque city of Nha Trang, the university provides a vibrant and conducive environment for students to thrive. Its curriculum is meticulously crafted to equip students with the skills and knowledge needed to navigate the dynamic world of telecommunications. With a focus on both theoretical understanding and practical application, students engage in hands-on experiences that prepare them for real-world challenges.

Profiles:

Experience:

At the Telecommunications University in Nha Trang, Vietnam, the educational journey transcends traditional boundaries, offering students a transformative experience in the dynamic realm of telecommunications. Nestled in the heart of Nha Trang, this institution cultivates an immersive learning environment that seamlessly blends academic rigor with practical application.Students embark on a journey of exploration, delving into cutting-edge technologies and emerging trends in the telecommunications landscape. The faculty, composed of industry experts and seasoned professionals, imparts invaluable insights, fostering a culture of innovation and inquiry. Through a well-rounded curriculum, students not only grasp theoretical foundations but also engage in hands-on projects that mirror real-world scenarios.The university’s commitment to technological excellence is mirrored in its state-of-the-art facilities and research centers, providing a crucible for groundbreaking discoveries. The collaborative atmosphere encourages teamwork and peer learning, enriching the overall educational experience.

Honors and Awards:

Tran Manh Hoang has garnered prestigious awards, underscoring his outstanding contributions and achievements. Recognized for his exceptional work in [specific field or industry], Hoang’s accolades highlight his commitment to excellence and innovation. Among the accolades are awards for [mention specific achievements, such as research breakthroughs, leadership, or notable projects].Hoang’s expertise and dedication have not gone unnoticed, with honors extending beyond individual accomplishments to encompass collaborative efforts and industry impact. Whether for [mention specific projects or initiatives], his contributions have consistently demonstrated a profound influence on [mention relevant aspects, such as technological advancements, business strategies, etc.].

 

Publications:

  1. Optimizing Duration of Energy Harvesting for Downlink NOMA Full-Duplex over Nakagami-m fading channel Cited by :57 ,published by : 218
  2. Performance analysis of full-duplex decode-and-forward relay system with energy harvesting over Nakagami-m fading channels      Cited by :  53 , published by : 2019
  3. Outage probability of NOMA system with wireless power transfer at source and full-duplex relay  Cited by : 49 , published by :2020
  4. Performance analysis of vehicle-to-vehicle communication with full-duplex amplify-and-forward relay over double-Rayleigh fading channels  Cited by :41 , published by : 2019 
  5. Analysis of partial relay selection in NOMA systems with RF energy harvesting  Cited by : 40 ,published : 2018
  6. On performance of two-way full-duplex communication system with reconfigurable intelligent surface  Cited by : 36 , published by : 2021`
  7. Outage Analysis of RF Energy Harvesting Cooperative Communication Systems Over Nakagami- Fading Channels With Integer and Non-Integer  Cited by : 36 , published : 2020
  8. Performance analysis of decode-and-forward partial relay selection in NOMA systems with RF energy harvesting Cited by :36 , published : 2018
  9. Outage Probability and Ergodic Capacity of User Clustering and Beamforming MIMO-NOMA Relay System With Imperfect CSI Over Nakagami- Fading Channels  Cited by : 33 , published : 2020 
  10. Performance Analysis of Full-Duplex Vehicle-to-Vehicle Relay System over Double-Rayleigh Fading Channels Cited by : 32 , published by : 2019

Statistical Process Control (SPC)

Statistical Process Control

Statistical Process Control (SPC) is a quality control and improvement methodology that uses statistical methods to monitor, control, and improve processes in various industries. SPC is particularly valuable in manufacturing and production settings but can be applied to virtually any process where data can be collected. Here are some key aspects and concepts related to SPC:

Process Variation

SPC is primarily concerned with understanding and managing two types of process variation: common cause variation (inherent to the process) and special cause variation (due to external factors or anomalies).

Control Charts

Control charts, also known as Shewhart charts or process-behavior charts, are a fundamental tool in SPC. They display process data over time, with upper and lower control limits to identify when a process is in or out of control.

Data Collection

SPC relies on the regular collection of data points or samples from a process. This data is then analyzed to assess process stability and identify any trends or deviations from expected performance.

Central Tendency and Variation

SPC often uses statistical measures of central tendency (e.g., mean or median) and measures of variation (e.g., range or standard deviation) to characterize a process and monitor its performance.

Process Capability Analysis

This involves assessing a process’s ability to produce products or services that meet customer specifications. Process capability indices like Cp, Cpk, Pp, and Ppk are used for this purpose.