Aims and Scope

Aim and Scope of JoMEET

The Journal of Marine Electrical and Electronic Technology (JoMEET) is dedicated to publishing high-quality, peer-reviewed research in the fields of electrical, electro marine, marine informatics, and marine technology. The journal aims to serve as a global platform for the exchange of innovative ideas, research findings, and practical applications in these areas, contributing significantly to the development of maritime technology and electrical engineering. JoMEET’s vision is to become the leading open-access journal for marine electrical and electronic research, fostering collaboration across industries and academic fields to address the technological challenges facing the maritime sector.

Unlike traditional journals that often have page constraints or narrow thematic focuses, JoMEET prioritizes the scientific rigor and validity of the research methodologies employed in each manuscript. The journal seeks to publish articles based on the quality of the research rather than thematic significance or length. This open approach encourages submissions from a variety of disciplines and invites exploration of connections between different technological fields, promoting a broader understanding of marine electrical and electronic systems. The journal also emphasizes interdisciplinary research that bridges gaps between marine technologies and electrical engineering, ensuring a dynamic and comprehensive exploration of the field.

Scope of JoMEET

JoMEET’s scope is wide-ranging, covering the following four main areas of research:

  1. Electrical:
    Topics within this category include a variety of electrical engineering subfields that are integral to modern technological advancements:
    • Intelligent Systems: Development and application of smart systems in industrial and everyday settings.
    • Power Engineering: Power generation, distribution, and management, including renewable energy sources.
    • Hybrid Systems: Integration of renewable energy sources with conventional energy systems to optimize efficiency.
    • Energy Management and Conservation: Techniques and technologies aimed at improving energy use and reducing consumption.
    • Control Systems: Design and implementation of control systems used in electrical devices and processes.
    • Machine Learning and Artificial Intelligence: Application of AI and ML techniques in electrical engineering for predictive maintenance, optimization, and automation.
    • Protection Systems: Development of systems to ensure the safety and integrity of electrical installations and networks.
  2. Electromarine:
    This area focuses on the application of electrical engineering in maritime and marine technologies:
    • Marine Power Systems: Electrical systems designed for maritime applications, including ships, offshore platforms, and other vessels.
    • Marine Diagnostic Instrumentation: The use of electrical technologies for monitoring and diagnosing marine equipment and conditions.
    • Offshore Power Engineering: Engineering solutions for generating and distributing power to offshore platforms.
    • Marine Modeling and Control: Control systems designed to optimize the performance and safety of maritime operations.
    • Electric Ship Systems: Electrical systems designed for the power generation and management aboard ships.
    • Blue Energy: Exploration and use of renewable marine-based energy sources such as tidal and wave energy.
  3. Marine Informatics:
    This area applies computing and information technology to the maritime industry:
    • Marine Digital Signal Processing: Signal processing techniques used in marine communication, navigation, and sensing technologies.
    • Intelligent Marine Informatics: The use of AI and machine learning to improve decision-making and efficiency in marine operations.
    • Computer-Aided Marine Systems: The development of computer-based tools to aid in the design and operation of marine systems, including simulations and modeling.
    • Educational Computer Programs for Marine Informatics: Computer-based educational resources aimed at training and informing marine industry professionals.
  4. Marine Technology:
    Marine technology focuses on the advanced technologies used in the maritime industry:
    • Remote Operated Vehicles (ROVs): The development and application of remotely operated vehicles for exploration and maintenance of underwater structures.
    • Submarine Operated Vehicles (SOVs): Technologies related to underwater vehicles that are either manned or remotely controlled.
    • Maritime Communication Systems: The design and implementation of communication systems used for navigation, safety, and operational coordination in maritime settings.
    • Sensor and Weapon Systems (SEWACO): The development of sensors and weapon control systems used on naval vessels and submarines.
    • Unmanned Underwater Vehicles (AUVs): Development of autonomous underwater vehicles for research and operational purposes.
    • Submersible Equipment: Technology used to operate underwater at great depths for exploration, research, and rescue operations.
    • Radar and Navigation: Advanced technologies for radar and navigation systems that ensure safe maritime operations.