Guiyi Dong

Welcome to my personal webpage! I am a doctoral student at Kobe University Graduate School of Maritime Sciences, affiliated with the Power Electronics Laboratory under the supervision of Professor Mishima, specializing in power electronics for wireless charging and induction heating applications. My research focuses on developing efficient and reliable power circuits to enable these technologies. On this page, you can learn more about my research interests, publications, and projects. Thank you for visiting!

Email / Orcid / Github

News

I designed a SiC MOSFET driver board, and the hardware is now open source.

Received the award[産業応用部門　優秀論文発表賞]

A Design of Carbon Neutral Port Bay City

Medical Electrical Maze Experiment

The homepage of the National University's 55 Engineering Departments has featured an article titled "Let's Build a Slayer Exciter Mini Tesla Coil Device

Education level

04/2022-Now, PhD at Kobe University Graduate School of Maritime Sciences.

04/2020-03/2022,　Postgraduate at Gunma University Graduate School of Science and Technology.

09/2015-06/2019, bachelor at School of Electrical and Information Engineering ,Shandong Jianzhu University.

Technology Ability

Embedded system design, development, and testing (STM32, Kinetis MCUs, FPGA, Arduino)

Embedded software (Keil, IAR, STM32CUBEIDE)

Programming: C, Python, C#, MATLAB, web development(HTML, CSS, and JavaScript).

PCB design (KiCAD).

Power electronics simulation(Psim, SIMetrix/SIMPLIS).

Digital circuit and analog circuit design.

AI: Stable diffusion, midjourney.

OS: Linux(Ubuntu),Windows

Linux web server management

Website design and management:Homepage of Lab

OpenCart deployment and maintenance.

Typesetting system: \( \LaTeX \)

Recent Projects

Direct ac-ac converter

The direct ac-ac converter is a practical circuit topology for high-efficient power conversion in induction heating(IH) and wireless power transfer (WPT) applications. The conventional Pulse Frequency Modulation (PFM) based power control scheme causes audible noises between the adjacent loads, which operate at different switching frequencies. As a solution for the technical issue, a new fixed-frequency power control methodology for a single-phase direct ac-ac converter is proposed in this research, featuring a wide range of soft switching operations and robustness for abnormal load conditions.

[特願 2023-6876，2023.1.19 三島智和, 董貴義, 大森英樹, 出願人：国立大学法人　神戸大学] [特願 2023-203221，2023.11.30 三島智和, 頼慶明, 董貴義, 出願人：国立大学法人　神戸大学]

Previous research

Dual-Active Single-Ended Wireless V2H System

The bidirectional Wireless Power Transfer (WPT) device for vehicle-to-house (V2H) uses a simple, compact single-ended converter and self-synchronized phase-difference control mechanism. This research proposes a way whereby phase difference control could be self-contained on the slave side without mutual communication. This method allows for high-power wireless transmission despite the low coupling coefficient between the transfer coils. The phase difference and transmission power can be altered by changing the MOSFET conduction time on one side without synchronizing the phases on both sides.

Notch Frequency Generation Methods in Noise Spread Spectrum

Two pulse coding control methods for generating notch frequency automatically in noise spread spectrum for switching DC-DC converters are proposed; these are based on our previously proposed method. Our two methods here generate the notch frequency Fn automatically according to the received frequency F in . The first one is a constant frequency PWM-controlled buck DC-DC converter where the clock frequency and coding pulse width are automatically set according to the frequency of the received signal to generate notch characteristics. The second one is a pulse frequency modulation (PFM) pulse coding DC-DC converter which generates a composite notch characteristic where both the constant pulse width and the periodic modulation coding pulse width are automatically matched with input frequency Fin.

Quadruped Robot with Remote Control using Arduino, Freescale KL Series Microcontroller, and PlayStation 2 Game Controller

This undergraduate capstone project involved the design and development of a quadruped robot capable of being remotely controlled. The robot's electronic system is powered by an Arduino microcontroller and a Freescale KL series microcontroller, providing a reliable and efficient control platform. The chosen method for remote control is a PlayStation 2 (PS2) game controller, allowing the user to seamlessly operate the robot's movements. The controller communicates with the microcontrollers to execute different actions, such as walking, turning, and other pre-programmed movements. The project required a thorough understanding of robotics, microcontroller programming, and wireless communication. The completed quadruped robot demonstrates the potential applications of such technology in various fields, including exploration, search and rescue, and entertainment.

Autonomous Two-Wheeled Self-Balancing Vehicle with Electromagnetic Signal Tracking Using Freescale Microcontrollers

In this project, I participated in two Freescale competitions that involved developing an autonomous two-wheeled self-balancing vehicle. The vehicle's control system is powered by a Freescale series microcontroller, which ensures efficient and reliable performance. The primary feature of this vehicle is its ability to automatically track electromagnetic signals, which allows it to achieve the goal of autonomous driving. By detecting and following these signals, the vehicle can navigate through various environments without human intervention. The project required a deep understanding of microcontroller programming, control systems, and signal processing. The successful development of this autonomous two-wheeled self-balancing vehicle showcases the potential of integrating such technology in various applications, such as transportation, logistics, and other areas where autonomous navigation is essential.

Publications&Awards

単相ダイレクトＡＣ−ＡＣコンバータとその電力制御方法，
特願 2023-203221，2023.11.30 三島智和, 頼慶明, 董貴義, 出願人：国立大学法人　神戸大学

広範囲な直流母線に対応するインターリーブ方式高電圧比双方向DC-DCコンバータ
劉士強, 董貴義, 賴慶明, 三島智和
電気学会研究会資料. HCA / 家電・民生研究会 [編] 2023 (15-17・22-30), 19-24, 2023-05 電気学会paper

パルスコーディングDC-DCコンバータにおける複合周波数ノッチ特性を有するスペクトラム拡散
董貴義 孫逸菲片山翔吾小堀康功桑名杏奈小林春夫三島智和
電気学会研究会資料. HCA / 家電・民生研究会 [編]掲載巻 2022 掲載号 21・23-31 電気学会paper

Power Control Scheme of Fixed-Frequency Single-Phase Direct AC-AC Converter for Induction Heating Applications
Guiyi Dong, Tomokazu Mishima, Hideki Omori
IEEJ Transactions on Industry Applications, vol. 143, no. 6, pp. 519-520, 2023.paper

A New Power Control of a Fixed-Frequency Single-Phase Direct AC-AC Converter Using a Bidirectional Switch for Induction Heating Applications
Guiyi Dong, Tomokazu Mishima, Hideki Omori
IEEJ Joint Technical Meeting on Semiconductor Power Converter/Motor Drive 2023 paper

ダイレクトAC-ACコンバータの電力制御回路及び電力制御方法，
特願 2023-6876，2023.1.19 三島智和, 董貴義, 大森英樹, 出願人：国立大学法人　神戸大学

A Dual-Active Single-Ended Wireless V2H System with Self-Synchronized Phase-Difference Control Method
Guiyi Dong; Hideki Omori; Genki Kengaku; Tomokazu Mishima; Jun Tanaka
2022 IEEE 7th Southern Power Electronics Conference (SPEC) | paper

A Dual-Active Single-Ended Wireless V2H System with Mutually Synchronized Phase-Difference Control Method
Guiyi Dong;Tomokazu Mishima;Hideki Omori
2022 IEEE 17th Conference on Industrial Electronics and Applications (ICIEA) | paper

Notch Frequency Generation Methods in Noise Spread Spectrum for Pulse Coding Switching DC-DC Converter
Guiyi Dong; Shogo Katayama; Yifei Sun; Yasunori Kobori; Anna Kuwana; Haruo Kobayashi
2022 IEEE 13th Latin America Symposium on Circuits and System (LASCAS) | paper

Band-select Noise Spread Spectrum Techniques for Pulse Coding Ripple-controlled Hysteretic Converter GuiYi Dong, S . Katayama ,Y . Sun, Y . Kobori, A . Kuwana, H . Kobayashi TJCAS 2021 paper

Adaptive Convergence Method of Notch Frequency in Noise Spread Spectrum for Pulse Coding Switching DC-DC Converter
Guiyi Dong; Shogo Katayama; Yifei Sun; Yasunori Kobori; Anna Kuwana; Haruo Kobayashi
2021 IEEE 14th International Conference on ASIC (ASICON) | paper

Analysis and Stability Evaluation of Ripple Injection Type Hysteretic Controlled Switching Converter
Guiyi Dong; Kento Itoi; Shogo Katayama; Yasunori Kobori
4th International Conference on Technology and Social Science (ICTSS 2020)At: Gunma, Japan | paper

EMI Reduction and Frequency Stabilization in Ripple Injection Type Hysteretic Controlled Switching Converter
Guiyi Dong; Kento Itoi; Shogo Katayama; Tran Minh Tri;Yasunori Kobori; Anna Kuwana; Haruo Kobayashi
2020 年度（第 11 回）電気学会東京支部栃木・群馬支所合同研究発表会 | paper

2022年電気学会産業応用部門技術委員会優秀論文発表賞

ICTSS best student award ICTSS 2020

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