Freshman |
Sophomore |
Junior |
Senior |
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|---|---|---|---|---|
Basic major |
General Physics Laboratory (I)(1) General Physics (I)(3) Calculus in Engineering (I)(3) Statics (3) Calculus in Engineering (Ⅱ)(3) General Chemistry (3) Introduction To Naval Architecture & Ocean Engineering(1) Engineering Linear Algebra (3) |
Dynamics (3) Python Programming(2) |
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Major required |
Fluid Mechanics(3) Basic Experiments in Engineering (1) Differential Equation in Engineering (3) Solid Mechanics(3) Engineering Basic Design (1) Applied Mathematics(3) Ship Calculations(3) |
Numerical Analysis(3) Ship resistance (3) Structural Mechanics(3) Production Engineering (3) Design of Welded Structures (3) Ship Vibration (I)(3) Welding Laboratory(1) Ship Resistance & Propulsion Laboratory (1) Computer Aided Ship Design (1) |
Structural Laboratory (1) Ship Motion & Ocean Engineering Laboratory (1) Vibration And Acoustics Laboratory (1) Offshore Structural Design (3) Ship Basic Design(3) |
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Optional Courses |
Introduction To Electrical Engineering (3) Ship Economic Engineering (3) Thermodynamics(3) Ship Hydrodynamics (3) Probability & Statistics (3) Ocean Wave Mechanics (3) |
Ship Motion (3) Engineering of Ocean Environment system (3) Introduction to Offshore Structure system (3) Engineering Materials (3) Heat Transfer (3) Ship Structural Design (3) Ship Propeller Design (3) Manufacturing System Engineering (3) Marine Equipment Design for Ocean Resourse Production(3) Finite Element Method(3) |
Smart Control Engineering(3) Computational Fluid Mechanics (3) Ship Equipments (3) Ship Vibration (II)(3) Special Lectures in Naval Architecture and Ocean Engineering (1) Optimum Design (3) Engineering Process for Ocean Resources (3) Applied Solid Mechanics (3) Data Science (3) Renewable Energy System (3) Structural Reliability and Risk Based Design (3) NAOE Capstone Design (I)(1) NAOE Capstone Design (II)(1) |
General Physics (I)(3)
1. To understand the concepts and mathematical descriptions of force and torque that generate motion.
2. To understand the laws of motion, and apply them to mechanical systems.
3. To study the phenomena involved in gravitation, mechanical oscillations, and wave motions.
4. To understand the nature of the scientific method and the field of physics.
General Physics Laboratory (I) (1)
1. Experimental skills
2. Analysis skills.
3. Conceptual learning
Statics (3)
This course aims to provide a systematic understanding of the types, characteristics, and interactions of forces, and to rigorously examine the conditions under which a body or structural system remains in static equilibrium. Additionally, by acquiring analytical techniques for determinate structures, students will develop the fundamental mechanics competencies required of engineering professionals.
Calculus in Engineering(Ⅰ) (3)
-Basic knowledge in Calculus
-Application of derivatives and integrals in engineering problem
Calculus in Engineering (Ⅱ) (3)
This course provides a deeper study of the principles, computations, and applications of differentiation and integration. It is designed to strengthen students’ understanding of advanced mathematical concepts required in various engineering disciplines.
In particular, the course focuses on the theory of Fourier series and the fundamental concepts of tensor theory.
General Chemistry (3)
Introduction To Naval Architecture & Ocean Engineering(1)
This course serves as an introductory program to naval architecture and ocean engineering. Students learn the fundamental principles and purposes of various ships and offshore structures, gaining a comprehensive understanding of the shipbuilding and marine industries as well as essential engineering knowledge of these systems. The class also covers basic engineering concepts and technical terminology that are foundational to subsequent major courses in the curriculum, utilizing a variety of audiovisual materials to enhance learning.
Engineering Linear Algebra (3)
Build a rigorous foundation in vectors, matrices, and linear transformations, then see how they power real systems—from PageRank and cryptography to AI pipelines. You’ll connect theory (eigenvalues, SVD, conditioning) to hands-on problem solving that engineers actually use.
Dynamics (3)
This course addresses the fundamental concepts and principles used to describe the motion of bodies, with an emphasis on examining the relationships between the forces and moments that generate such motion. Students will systematically study the kinematics and equations of motion for particles and rigid bodies, and acquire key analytical techniques—including the principles of energy and momentum conservation—to develop the ability to quantitatively analyze engineering problems. Through this process, the course establishes the foundational mechanical framework necessary for advanced studies in mechanical/structural dynamics and control.
Python Programming(2)
A fast, practical gateway to AI/data work. Learn Python essentials and data workflows through weekly labs that clean, analyze, and visualize real datasets; finish with a concise mini-project.
Fluid Mechanics(3)
To acquire basic knowledge regarding the characteristics of fluids, fluid statics and fluid kinematics.
To develop engineering capabilities required to solve various flow related problems.
Basic Experiments in Engineering (1)
1. Acquisition of fundamental laboratory knowledge and safety protocols required for various major-related experiments.
2. Introduction to the definitions of basic physical quantities used in engineering, such as length, mass, time, and temperature.
3. Lectures on measurement methodologies and the use of essential sensors and instruments for data acquisition.
4. Training on experimental data analysis, including error analysis and uncertainty estimation to ensure technical accuracy.
Differential Equation in Engineering (3)
1.Understanding of concept and principle of engineering Mathematics, 2.lement knowledge to apply engineering Mathematics to the related Mechanics, 3.Creative analysis ability to utilize engineering Mathematics through the problem analysis
Solid Mechanics(3)
Calculation of stress and strain under various loading conditions; mechanical properties of engineering materials and methods for their evaluation; stress transformation and the construction of Mohr’s circle.
Engineering Basic Design (1)
Through a project-based, systematic approach to engineering design, students learn how to effectively carry out team-based tasks and design projects by applying conceptual design methods and project management tools. In addition, they learn how to systematically present and report design project outcomes, while gaining useful insights into team behavior and dynamic team activities.
Applied Mathematics(3)
This course is designed to provide students with the fundamental mathematical knowledge necessary to understand mechanical and physical phenomena covered in the undergraduate curriculum.
Particular emphasis is placed on complex numbers, which are essential for the theoretical analysis of fluid mechanics, as well as on the study of infinite series such as the Taylor series.
The course also covers Fourier series, integration, transformation techniques, and basic methods for solving partial differential equations.
Ship Calculations (3)
- Terminology and notation in naval architecture
- Evaluation of intact & damage stability of ships
Numerical Analysis (3)
This course covers fundamental and advanced numerical methods, including solutions of nonlinear equations, algorithms for systems of linear equations, numerical integration, and numerical methods for ordinary differential equations (both initial-value and boundary-value problems).
A particular emphasis is placed on the Banach Fixed-Point Theorem, studying its theoretical foundation and exploring how it underpins and unifies a wide range of numerical analysis techniques.
Ship resistance (3)
Based on the understanding the physics and basic theory of ship resistance, teach the knowledge of wave making resistance, relationship between hull form design and resistance together with hull form optimization, the full scale ship power and speed prediction from model ship test, the frictional resistance and mechanism of drag(frictional) reduction and finally the type of high speed ships together with hull form characteristics.
Structural Mechanics (3)
To design various machines and structures, structural analysis—namely, calculating the effects of external loads such as displacement and strain—is essential. Structural mechanics provides the fundamental principles required for such analyses. This course covers the basic concepts and applications of various energy methods used to analyze modern structures, which are increasingly large and complex and subjected to diverse loads and boundary conditions.
Production Engineering (3)
1. General overview of the shipbuilding industry and the fundamental principles of ship production management.
2. Understanding the entire sequence of ship construction, starting from initial design to final delivery.
3. In-depth study of technical features in each production stage: material processing, block assembly, pre-outfitting, and grand assembly (erection).
4. Exploration of launching methods, shipyard layouts, and the latest technological trends in smart and eco-friendly shipbuilding.
Design of Welded Structures (3)
An overview of various welding processes, including their characteristics and applications; metallurgical and mechanical properties of welds and their behavior; design and strength calculation methods for welded joints.
Ship Vibration (I)(3)
This lecture aims to study fundamental theory to be applicable for low vibration design of ship and offshore structures including machinery. For the purpose, in this lecture, various vibration phenomena with excitation sources are introduced. Then, free and forced vibration analysis method for one and multi-degree of freedom system is introduced for predicting and reducing the vibration system. Moreover various examples to analysis vibration characteristics, to predict vibration response and to reduce the response are also introduced.
Welding Laboratory(1)
Practical training in manual welding and CO₂ gas welding; hands-on practice in setting welding parameters for weld quality control; practical training in weld inspection techniques.
Ship Resistance & Propulsion Laboratory (1)
The resistance test, propeller open water test and self-propulsion tests by several models are conducted to predict the full scale performance such as power and speed. By doing these experiments, the data acquisition, experimental technique and experimental uncertainty are understood.
By the resistance, POW and self-propulsion tests with models, the full scale power and speed prediction techniques together with hull form and propulsor design techniques are educated
Computer Aided Ship Design (1)
Provides the mathematical representation methods for three-dimensional free-form hull shapes and enables the generation and transformation of various hull forms through computer-based techniques.
Structural Laboratory (1)
There are theoretical, numerical, and experimental methods for evaluating structural behaviour. Among these, the experimental approach provides the most realistic means of analyzing the behavioral characteristics and phenomena exhibited by structures under external loads. This course offers hands-on practice with representative techniques and applications for experimentally assessing the behaviour characteristics of structures, using structural models.
Ship Motion & Ocean Engineering Laboratory (1)
In 2-D wave tank, it is performed of a generation, measurement, analysis of a regular and irregular waves to understand water wave phenomena and a physical modeling and a roll free decay test and analysis of motion RAO for hydrodynamic assessment of floating structure.
Vibration And Acoustics Laboratory (1)
In this lecture, fundamental theories applied for vibration and noise measurement are introduced. In addition, how to set up the system to measure noise and vibration as well as how to use individual instrument is demonstrated. Then, students by themselves do various experiments to measure environmental noise, free and forced vibration responses of a beam, damping property of a beam, absorption property of material and so on.
Offshore Structural Design (3)
It is to introduce a various offshore structures and study a met-ocean environment, wave mechanics, an evaluation of ocean environmental external loading, and hydrodynamics of offshore structures.
Ship Basic Design(3)
Provides the fundamental knowledge required for designing high-performance and economically efficient ships. Based on this foundational understanding, the procedure for determining the principal dimensions of a ship and establishing its general arrangement is organized and summarized.
Introduction To Electrical Engineering (3)
This course covers the fundamental concepts of electrical and electronic engineering required in the field of naval architecture and ocean engineering. It is designed to help students understand the basic principles of electrical engineering through practical applications such as marine electrical systems, electric propulsion, instrumentation and control, and power management in ship and offshore environments.
Ship Economic Engineering (3)
Understanding the time value of money, evaluating the economic feasibility of various design alternatives, and acquiring the ability to analyze engineering investment options.
Thermodynamics(3)
Thermodynamics is the study of energy in its various forms and the processes of its transformation, serving as a fundamental subject across all fields of engineering.
It deals with the properties of matter, the transfer of energy, and the interrelationship between work and heat, providing the basis for analyzing the performance and efficiency of various engineering systems such as engines, refrigerators, and power plants.
Thermodynamics is also centered on the principles of energy conservation (the First Law) and entropy (the Second Law), which are essential for understanding the direction and limitations of energy conversion in natural phenomena.
Through this course, students develop the theoretical foundation necessary to interpret real engineering problems and to design efficient and sustainable energy systems.
Ship Hydrodynamics (3)
To understand various description of fluid flow and difference between differential and integral analysis method
To enhance problem solving capability for the potential and external flow for marine hydrodynamics applicationsx
To study the principle of viscous and turbulent flow toward the understanding of complex flow phenomena in industry applications
Probability & Statistics (3)
Ocean Wave Mechanics (3)
This course begins with a brief review of fundamental fluid mechanics and then develops the analytical framework of linear (small-amplitude) wave theory. Topics include the formulation and solution of corresponding boundary-value problems, properties of progressive waves, characteristics of standing waves, wave energy and group velocity, and methods for wave-force calculation on marine structures.
Ship Motion (3)
- Rigid body dynamics
- Fluid mechanics and potential flow
- Seakeeping and Maneuvering models
Engineering of Ocean Environment system (3)
This course aims to develop fundamental mechanical and fluid-dynamical knowledge essential for understanding marine environmental systems and their engineering applications. It also introduces the physical, biological characteristics of seawater and examines marine environmental pollution from an interdisciplinary perspective.
Introduction to Offshore Structure system (3)
This course explores the history of offshore resource development and the evolution of various types of offshore structures. It provides an understanding of their components, characteristics, and application areas, enabling students to acquire fundamental engineering knowledge related to offshore structures used for offshore resource development.
Engineering Materials (3)
This course provides a broad understanding of the fundamental theories of engineering materials, their properties, and processing characteristics, enabling students to acquire practical knowledge for material selection in the shipbuilding industry.
Heat Transfer (3)
This course covers the physical phenomena of heat and mass transfer and the formulation and analysis of their mathematical models.
It includes the derivation of the fundamental equations for the three modes of heat transfer—conduction, convection, and radiation—and the analysis of related example problems.
Both one-dimensional and multidimensional, steady and unsteady heat transfer problems are addressed.
Applications such as heat exchangers, fins, pipes, heating and cooling systems, and electronic devices are introduced and analyzed.
Ship Structural Design (3)
For a ship to safely perform its intended functions not only in normal wave conditions but also in extreme and accidental environments, it must possess sufficient structural strength and safety. This course covers the structural strength of hull structural members as well as the hull girders—including buckling and collapse—along with methods for calculating applied loads and comprehensive approaches to evaluating structural safety of ship hull structures.
Ship Propeller Design (3)
To understand the propulsive elements of the ship.
To learn design and evalation procedures for the marine propellers.
Manufacturing System Engineering (3)
Production is divided into three areas—production technology, production management, and industrial economics—and each area is explained in detail with an emphasis on their interrelationships. Through a systematic and analytical approach, the course enables easier access to and understanding of production systems engineering.
Marine Equipment Design for Ocean Resourse Production (3)
It is to introduce the equipment system of offshore structure including topside process system. subsea system, drilling system, and station keeping system for oil & gas production, storage, and transport.
Finite Element Method(3)
1. Study of elasticity theory and governing equations, such as equilibrium and compatibility, to describe the deformation behavior of solids under external loads.
2. Introduction to the theoretical concepts of the Finite Element Method (FEM) for obtaining approximate solutions to complex engineering problems.
3. Formulation of element stiffness matrices and global assembly procedures based on energy principles or weighted residual methods.
4. Practical application of FEM to real-world structural analysis problems using computational tools to predict stress and strain distributions.
Smart Control Engineering(3)
As teaching the basic knowledge about modern control theories such as optimal control, adaptive control, and nonlinear control, it is intended to cultivate the design ability of control algorithm and control system for target systems applicable in naval architecture and ocean engineering.
Computational Fluid Mechanics (3)
Turn PDEs of fluid motion into predictive simulations for ship design. Learn discretization, turbulence/free-surface modeling by visualizing numerical resistance tests for a real hull.
Ship Equipments (3)
It is to introduce various ships and equipment of cargo handling system, accommodation, power generation system, propulsion system, steering gear & rudder system, piping system, anchor & mooring system, and study an arrangement on ships.
Ship Vibration (II)(3)
Ship vibration is generated by machinery including its propulsion system and ocean environment. The vibration is objectionable when it may result in excessive stresses on structural and mechanical components, adverse effects on reliability or serviceability of machines and equipment, and adverse comments from crew and passengers on vibration that interferes with duties or reduces comfort. Hence, reducing ship vibration is regarded as a key technology to build high-quality ships. In this lecture, based on the vibration theory for the one and multi degree-of-freedom system treated in Ship vibration, vibration theory for continuous system and fundamental methods for anti-vibration design and countermeasures for excessive vibration are introduced. Then, the followings are studied to increase the ability of low-vibration design for high-quality ship design and construction. 1) Phenomena and excitation sources of ship vibration 2) Analysis methods of ship vibration 3) Anti-vibration design
Special Lectures in Naval Architecture and Ocean Engineering (1)
This course introduces the practical applications of engineering education with a focus on the shipbuilding and offshore industries.
It aims to cultivate cultural awareness, ethical responsibility, and professional maturity among students of naval architecture and ocean engineering, preparing them to become future leaders in society.
In addition, the course provides insights into technological trends and future directions of development as anticipated by the maritime and offshore industries, which play a leading role in global economic activity.
Optimum Design (3)
Optimal design has evolved from classical mathematical approaches to various modern methodologies, including applications in artificial intelligence and deep learning, and now serves as a fundamental theory with broad practical applications. The course covers the foundational principles of optimal design and their application, along with analytical and numerical methods used in optimization.
Engineering Process for Ocean Resources (3)
Applied Solid Mechanics (3)
Strain transformation and the construction of Mohr’s circle; equations for bowing deformation and deflection curves; design methods and strength calculations for columns.
Data Science (3)
Introducing the fundamental theories, algorithms, and applications of machine learning, with an emphasis on understanding the core concepts of the field. Machine learning is a key technology widely utilized in big data, engineering, and various scientific domains. Through machine learning, computer systems adjust their performance based on experience derived from observed data.
Renewable Energy System (3)
This course provides a foundational understanding of the principles and technologies of renewable energy systems. It covers the characteristics and conversion methods of major renewable resources—including solar, wind, hydro, bioenergy, and geothermal energy—and introduces key topics such as system design, energy efficiency, and resource assessment. The course equips students with essential knowledge for advancing sustainable energy technologies and pursuing further study or professional work in the renewable energy field.
Structural Reliability and Risk Based Design (3)
In defining the various basic variables that must be considered for structural strength evaluation or design, uncertainty is inherently present. To rationally incorporate this uncertainty into the structural design process, it must be addressed using reliability theory rather than deterministic methods. This course covers the principles of reliability theory and its applications for evaluating the strength and safety of ship hull structures.
NAOE Capstone Design (I)/(II)
By utilizing the major of shipbuilding and marine engineering and related knowledge, the company conducts analysis, design, production, and evaluation of various shipbuilding and marine systems, and fosters creativity, practical skills, teamwork and leadership.