Program: B.S., Mechanical Engineering
Mechanical Engineering majors at CSUN receive a solid education in the fundamentals of the discipline augmented by hands-on experience that employers have found to be invaluable. Design concepts and projects are integrated throughout the curriculum.
The freshmen and sophomore years provide the student with a breadth of knowledge that is required in specialized courses and in the career work of the mechanical engineer. During these years, students take courses in mathematics, chemistry, physics, computer programming, engineering materials, engineering mechanics, electrical systems and mechanical design. The junior year courses include engineering economics, engineering dynamics, strength of materials, thermodynamics, fluid mechanics, heat transfer, mechanical design, the numerical analysis of engineering systems, and computer-aided analysis and design.
The senior year is composed of a group of required and elective courses that are related to the student’s area of specialization within Mechanical Engineering. The required courses include system dynamics, mechatronics and two semesters of senior design. Students can take their electives to obtain more in-depth knowledge in the following areas: aerospace engineering, automotive engineering, controls engineering, environmental engineering, mechanical design and thermal-fluid systems.
The Mechanical Engineering department takes a practical approach to engineering, offering hands-on design experience as well as theoretical knowledge. That’s an advantage on the job because our graduates have had experience constructing projects, not just analyzing and designing them. A key to this practical training is the department’s Senior Design Program, which is modeled on the industry work groups that students will encounter on the job. Like professional engineers, students design and develop a project, from conception through manufacture. In the process, they gain valuable experience in working as a team, overcoming technical and management challenges, and developing communication skills. Past senior design projects have included an autonomous intelligent ground vehicle, battle-bots, a Formula SAE race car, a human-powered vehicle, unmanned aerial systems, and systems for petroleum-polluted soil and water cleanup.
The Mechanical Engineering program assumes that students have a strong high school preparation in science, mathematics and English. High school courses should include four years of mathematics, four years of English and at least one year of Chemistry and Physics with labs. The mathematics courses should include geometry, trigonometry and algebra. Calculus is desirable.
CSUN provides the opportunity for students who have not had a complete background of pre-engineering work in high school to take courses to prepare for the major. These additional courses will not count toward the major and may increase the time to graduate. CSUN provides testing as outlined below to ensure that students start their engineering coursework at an appropriate level.
Placement Exam Requirements
Students entering the Mechanical Engineering program need to take the following exams:
- The Mathematics Placement Test (MPT) is required prior to enrollment in MATH 150A. Students should take this exam before enrolling in their classes so they may be placed in the appropriate mathematics course. Students with scores of 4 or 5 on the AP Calculus AB or BC exams are exempt from the MPT.
- The Chemistry Placement Test (CPT) is required with a minimum score of 40 prior to enrolling in CHEM 101. Students who have had high school chemistry and expect to enroll in CHEM 101 must take this test regardless of their score on the AP Chemistry exam. Students who do not achieve this CPT score must complete CHEM 100 with a grade of “C” or better before taking CHEM 101.
Special Grade Requirements
- All students must complete the lower division writing requirement before enrolling in any 300-level engineering courses.
- Students who have completed 56 units and have met the lower division writing requirement are required to take the Upper Division Writing Proficiency Examination (UDWPE) as early as possible and no later than the semester in which 75 units are completed. Students who have not attempted the exam by the completion of 75 units will have a hold placed on their subsequent class registration and may delay their graduation.
- A grade of “C-” or better is required in all courses in the major. A grade of “C” or better is required in all undergraduate transfer courses.
- Senior-year courses cannot be taken unless the student has previously completed, or is concurrently completing, all freshman-, sophomore- and junior-year requirements.
- A grade of “C” or higher is necessary in MATH 150B to meet the prerequisite requirements for the next-level math courses.
1. Lower Division Required Courses (47 units)
a. Freshman Year
CHEM 101 General Chemistry and Lab (4)
CHEM 101L General Chemistry and Lab (1)
MATH 150A Calculus I (5)
MATH 150B Calculus II (5)
ME 101/L Introduction to Mechanical Engineering and Lab (1/1)
ME 186/L Computer-Aided Design and Lab (1/1)
PHYS 220A Mechanics (3)
PHYS 220AL Mechanics Lab (1)
b. Sophomore Year
2. Upper Division Required Courses (52 units)
a. Junior Year
AM 316 Engineering Dynamics (3)
AM 317 Mechanics Lab (1)
CE 340 Strength of Materials (3)
ME 309 Numerical Analysis of Engineering Systems (2)
ME 330 Machine Design (3)
ME 335/L Mechanical Measurements and Lab (1/1)
ME 370 Thermodynamics (3)
ME 375 Heat Transfer I (3)
ME 386/L Computer-Aided Analysis and Design and Lab (2/1)
ME 390 Fluid Mechanics (3)
MSE 304 Engineering Economic Analysis (3)
b. Senior Year
ME 384 System Dynamics: Modeling, Analysis and Simulation (3)
ME 435/L Mechatronics and Lab (2/1)
ME 486A Senior Design in Mechanical Engineering I (2)
ME 486B Senior Design in Mechanical Engineering II (2)
ME 491 Experimental Methods in Thermal-Fluids Systems (1)
c. Upper Division Senior Electives (12 units)
Students must select 12 units of electives from 400- and/or 500-level engineering courses. These electives, together with the required senior-year courses listed above, constitute the student’s Mechanical Engineering senior year. The elective program must be approved by the Mechanical Engineering department before the student files a graduation check. Up to 6 units from the following list of non-ME courses may be taken as senior electives.
AM 410 Vibration Analysis (3)
CE 460/L Engineering Hydrology and Lab (2/1)
CE 487 Water Pollution (3)
ECE 410/L Electrical Machines and Energy Conversion and Lab (3/1)
ECE 411 Electric Power Systems (3)
ECE 412 Power Electronics (3)
ECE 420 Digital Systems Design with Programmable Logic (3)
ECE 425/L Microprocessor Systems and Lab (3/1)
ECE 440/L Electronics II and Lab (3/1)
ECE 501 Introduction to Biomedical Engineering (3)
MSE 527/L Mechanical Behavior of Materials and Lab (2/1)
3. General Education (27 units)
Undergraduate students must complete 48 units of General Education as described in this Catalog.
21 units are satisfied by coursework in the major. Completion of the Mechanical Engineering major satisfies A3 Critical Thinking. 6 units of Physical Science may be used to satisfy sections B1-3. MATH 150A satisfies Basic Skills B4 Mathematics/Quantitative Reasoning; ME 370 satisfies B5 Scientific Inquiry and Quantitative Reasoning; MSE 304 satisfies 3 units of upper division D1 Social Sciences; and ME 101/L and ME 209 satisfy E Lifelong Learning.
Total Units in the Major: 99
General Education Units: 27
Total Units Required for the B.S. Degree: 126
Department of Mechanical Engineering
Chair: Hamid Johari
Jacaranda Hall (JD) 4513
Student Learning Outcomes
The undergraduate mechanical engineering program should prepare students to enter the engineering profession as skilled practitioners who can make solid contributions to the field, find job satisfaction and have lifelong careers. To accomplish these overall goals, during the first few years following program completion, graduates are expected to:
- Have an engineering job or a position that utilizes the application of their engineering education in the workplace.
- Demonstrate a record of professional development activities related to the successful practice of engineering.
- Accept additional responsibilities to meet evolving workplace needs and be regarded by colleagues and supervisors as an effective member of their organization.
Student Learning Outcomes
Graduates will have an ability to:
- Identify, formulate and solve complex engineering problems by applying principles of knowledge of engineering, science and mathematics.
- Apply the engineering design process to produce solutions that meet specified needs with consideration for public health and safety, and global, cultural, social, environmental, economic and other factors as appropriate to the discipline.
- Develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
- Communicate effectively with a range of audiences.
- Recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic environmental, and societal contexts.
- Recognize the ongoing need to acquire new knowledge, to choose appropriate learning strategies, and to apply this knowledge.
- Function effectively as a member or leader of a team that establishes goals, plan tasks, meets deadlines, and creates a collaborative and inclusive environment.