Program Overview

  • Duration

    1 Year (Self-Paced)

    Can be done in 6 months

  • Total Courses

    10

  • Total Credit Hours

    60

The Aerospace Engineering program at Hudson Bay University is dedicated to preparing students for careers in the aerospace industry. Students delve into the principles of aerodynamics, spacecraft design, and aerospace technology. They gain the knowledge and skills necessary to contribute to the development of aircraft and spacecraft, as well as innovations in the field of aerospace engineering.

ENGINEERING FUNDAMENTALS AND TECHNICAL PROFICIENCY:

The College of Engineering is designed to establish a strong foundation in engineering fundamentals and technical proficiency. Students start by building a deep understanding of core engineering disciplines and gain hands-on experience in problem-solving and innovation. This technical base prepares students for a successful career in the dynamic field of engineering.


REAL-WORLD APPLICATIONS AND INDUSTRY PARTNERSHIPS:

Beyond the classroom, our College of Engineering places a significant emphasis on real-world applications and industry partnerships. Students have opportunities to work on engineering projects, collaborate with engineering firms, and engage in research with cutting-edge technology. These experiences not only enhance their practical engineering skills but also provide valuable insights into the industry.


GLOBAL ENGINEERING CHALLENGES AND INTERNATIONAL COLLABORATIONS:

The College of Engineering at Hudson Bay University is committed to addressing global engineering challenges and fostering international collaborations. Our curriculum explores international engineering practices and encourages students to engage in projects with global impact. Additionally, we offer study abroad programs and collaborate with engineers from around the world, enabling students to gain a global perspective on engineering.

Advanced Fields in Engineering explores specialized and advanced topics in engineering disciplines. The course content may vary, covering specific engineering subfields, research areas, and advanced methodologies.


Latest Developments in Engineering explores cutting-edge developments in engineering disciplines. Topics may include emerging technologies, research trends, and their impact on various engineering fields.


Engineering Numerical Methods equips students with numerical techniques for solving engineering problems. Topics include approximation methods, interpolation, and numerical solutions to differential equations.


E-Engineering explores the principles and applications of electrical engineering in electronic systems. Students will delve into electronic circuits, digital devices, and their use in various electronic applications.


Engineering Management focuses on the principles and practices of managing engineering projects and teams. Students will learn about project planning, leadership, and the effective management of engineering resources.

Explores the principles and dynamics of space flight. Students study orbital mechanics, spacecraft propulsion, and celestial navigation, essential knowledge for careers in aerospace and space exploration.


Offers an in-depth study of aerodynamics in aerospace engineering. Students explore advanced aerodynamic principles, computational methods, and their applications in aircraft and spacecraft design.


Introduction to propulsion systems in aerospace engineering. Students learn about various propulsion technologies, including jet engines and rocket propulsion, essential for understanding aircraft and spacecraft propulsion.


Focuses on the principles and applications of digital control systems in aerospace engineering. This course equips students with the knowledge and skills to design, analyze, and implement digital control systems for aerospace applications, essential for aerospace control engineers.


Examines the behavior of fluid flows in aerospace systems. Students study aerodynamics, propulsion, and fluid dynamics in the context of aerospace engineering, gaining insights into how fluids behave and their impact on aircraft and spacecraft.

Cost of Attendance

Tuition Fee Breakdown Cost
MASTER'S DEGREE (ME) $27,000
Medical Insurance $0.00
Personal Expenses $0.00
Study Materials $0.00
Food Cost $0.00
Total Tuition Fee $27,000
WHERE AFFORDABILITY

Meets Opportunity

At Hudson Bay University, we believe in where affordability meets opportunity. Our commitment to accessible education ensures that quality learning doesn't come with a hefty price tag. We open the doors to knowledge, offering students the chance to thrive without the burden of overwhelming tuition fees, empowering them for a brighter future.

Our Eligibility Criteria

Explore HBU’s Eligibility Criteria for Students Worldwide

Eligibility Criteria

Bachelor's Degree or equiv. international education

Credit Hours

60

Course Duration

1 Year (Self-Paced)

Courses Offered

10

Engineering Ethics (ENG-116)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Engineering Ethics
     Putting The Issues In Context
  In Section 2 of this course you will cover these topics:
     The Role Of Professional Codes Of Ethics
  In Section 3 of this course you will cover these topics:
     The Engineer'S Responsibilities To Society
  In Section 4 of this course you will cover these topics:
     The Engineer'S Obligations Of Loyalty To Employer
  In Section 5 of this course you will cover these topics:
     Changing Engineers And Engineering

Latest Developments In Engineering (ENG-163)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction
     Vectors And Tensors
     Stress
  In Section 2 of this course you will cover these topics:
     Principal Stresses And Principal Axes
     Analysis Of Deformation
     Velocity Fields And Compatibility Conditions
  In Section 3 of this course you will cover these topics:
     Constitutive Equations
     Isotropy
     Mechanical Properties Of Real Fluids And Solids
  In Section 4 of this course you will cover these topics:
     Derivation Of Field Equations
     Field Equations And Boundary Conditions In Fluid Mechanics
  In Section 5 of this course you will cover these topics:
     Some Simple Problems In Elasticity
     Stress, Strain, And Active Remodeling Of Structures

Engineering Numerical Methods (ENG-269)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     An Essay On Numerical Methods
     Numbers
     Function Evaluation
     Real Zeros
     Complex Zeros
     Zeros Of Polynomials  
     Linear Equations And Matrix Inversion
     Random Number
     The Difference Calculus
  In Section 2 of this course you will cover these topics:
     Roundoff
     The Summation Calculus
     Infinite Series
     Difference Equations
     Polynomial Interpolation
     Formulas Using Function Values
     Error Terms
     Formulas Using Derivatives
     Formulas Using Differences
  In Section 3 of this course you will cover these topics:
     Formulas Using The Sample Points As Parameters
     Composite Fornulas
     Indefinite Integrals
     Introduction To Differential Equations
     A General Theory Of Predictor-Corrector Methods
     Special Methods Of Integrating Simple Differential Equations “
     Least Square Method
     Orthogonal Functions
     Rational Function Approximation
  In Section 4 of this course you will cover these topics:
     Chebyshev Approximation: Theory
     Chebyshev Approximation: Practice
     Fourier Series
     Convergence Of Fourier Series
     The Fast Fourier Transform
     The Fourier Integral: Non- Periodic Functions
     A Second Look At Polynomial Approximation- Filters
     Integrals And Differential Equations
     Design Of Digital Filters
  In Section 5 of this course you will cover these topics:
     Quantization Of Signals
     Sum Of Exponentials
     Laplace Transform
     Simulation And Methods Of Zeros And Poles
     Approximation To Singularities
     Optimization
     Linear Independence
     Eigenvalues Eigenvectors Of Hermitian Matrices
     The Art Of Computing For Scientists And Engineers

E-Engineering (ENG-516)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Quantities And Units
     Voltage, Current And Resistance
     Ohms Law, Energy And Power
  In Section 2 of this course you will cover these topics:
     Series Circuit
     Parallel Circuits
     Series-Parallel Circuits
     Magnetism And Electromagnetism
     Introduction To Alternating Current And Voltage
     Capacitors
  In Section 3 of this course you will cover these topics:
     Rc Circuits
     Inductors
     Rl Circuits
     Rl Circuits And Resonance
  In Section 4 of this course you will cover these topics:
     Transformers
     Time Response Of Reactive Circuits
     Diodes And Applications
  In Section 5 of this course you will cover these topics:
     Transistors And Applications
     The Operational Amplifier
     Basic Op-Amp Circuits
     Special-Purpose Op-Amp Circuits
     Measurement, Conversion, And Control

Engineering Management (ENG-626)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Engineering Management
     Planning
     Organizing
  In Section 2 of this course you will cover these topics:
     Leading
     Controlling
     Cost Accounting
  In Section 3 of this course you will cover these topics:
     Financial Accounting And Analysis
     Managerial Finance
     Marketing Management
  In Section 4 of this course you will cover these topics:
     Engineers As Managers/Leaders
     Ethics In Engineering/Business Management
     Web-Enabled Engineering And Management Enablers
  In Section 5 of this course you will cover these topics:
     Globalization
     Engineering Management In The New Millennium

Non-Linear Systems (AEE-033)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Non-Linear Systems
     Phase Plane Analysis
  In Section 2 of this course you will cover these topics:
     Fundamentals Of Lyapunov Theory
     Advanced Stability Theory
  In Section 3 of this course you will cover these topics:
     Describing Function Analysis
     Feedback Linearization
  In Section 4 of this course you will cover these topics:
     Sliding Control
     Basic Concepts In Adaptive Control
  In Section 5 of this course you will cover these topics:
     Control Of Multi-Input Physical Systems

Space Flight Dynamics (AEE-047)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Spaceflight
     Two-Body Orbital Mechanics
  In Section 2 of this course you will cover these topics:
     Geocentric Orbits And Trajectories
     Time Of Flight
  In Section 3 of this course you will cover these topics:
     Interplanetary Tranfers
     Vehicle And Booster Performance
  In Section 4 of this course you will cover these topics:
     Atmospheric Entry
     Orbital Elements And Earth Tracks
  In Section 5 of this course you will cover these topics:
     The Ballistic Missile
     Attitude Dynamics And Control

Advanced Aerodynamics (AEE-111)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Aerospace Engineering
     Preliminary Estimate Of Take-Off Weight
     Wing Loading Selection
  In Section 2 of this course you will cover these topics:
     Main Wing Design
     Fuselage Design
     Horizontal And Vertical Tail Design
  In Section 3 of this course you will cover these topics:
     Engine Selection
     Take-Off And Landing
     Enhanced Lift Design
  In Section 4 of this course you will cover these topics:
     Structural Design And Material Selection
     Static Stability And Control
  In Section 5 of this course you will cover these topics:
     Cost Estimate
     Design Summary And Trade Study

Digital Control System (AEE-840)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Digital Systems
     Discrete-Time Systems And The Z-Transform  
     Sampling And Reconstruction
  In Section 2 of this course you will cover these topics:
     Open-Loop Discrete-Time Systems
     Closed-Loop Systems
     System Time-Response Characteristics
  In Section 3 of this course you will cover these topics:
     Stability Analysis Techniques
     Digital Controller Design
     Pole-Assignment Design And State Estimation
  In Section 4 of this course you will cover these topics:
     Linear Quadratic Optimal Control
     Sampled-Data Transformation Of Analog Filters
     Digital Filter Structures
  In Section 5 of this course you will cover these topics:
     Microcomputer Implementation Of Digital Filters
     Finite-Word Length Effects

Aerospace Fluid Flows (AEE-888)

TOPICS COVERED IN THIS COURSE
  In Section 1 of this course you will cover these topics:
     Introduction To Viscous Flows
     Integral Equations And Solutions For Laminar Flow
  In Section 2 of this course you will cover these topics:
     Exact And Numerical Solutions For Laminar Constant-Property Incompressible Flows  
     Compressible Laminar Boundary Layers  
  In Section 3 of this course you will cover these topics:
     Transition To Turbulent Flow
     Wall-Bounded, Incompressible Turbulent Flows
  In Section 4 of this course you will cover these topics:
     Internal Flows  
     Free Shear Flows
  In Section 5 of this course you will cover these topics:
     Wall-Bounded Turbulent Flows With Variable Density And Heat And Mass Transfer  
     Three-Dimensional External Boundary Layer Flows