2022-2023 Undergraduate Catalog

Nov 12, 2024

2022-2023 Undergraduate Catalog [Archived Catalog]

Agricultural and Biosystems Engineering (B.S.)

Location(s): Brookings Main Campus

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Program Coordinator/Contact

Kasiviswanathan Muthukumarappan, Interim Department Head, Distinguished Professor
Department of Agricultural and Biosystems Engineering
Raven Precision Agriculture Center 136
605-688-5143

Program Information

Agricultural and Biosystems Engineering is the science of engineering applied to the products and processes of agriculture and related industries. Design projects solicited from industry provide students with relevant “real world” design experience. This provides hands on learning in variety of technical areas such as natural resource management, irrigation and drainage, water resources development, machine dynamics and design, precision agriculture, agricultural power, properties and processing of biological materials, environmental control for livestock, indoor air quality, structures, control and disposal of agricultural wastes, computers, or instrumentation. To earn the Bachelor of Science Degree in Agricultural and Biosystems Engineering, students must have an average grade of “C” or better in courses taken and required in the ABE curriculum and take the Fundamentals of Engineering examination prior to graduation.

Program Educational Objectives

A few years after graduation, SDSU ABE graduates will:

Use methods of analysis involving use of mathematics, fundamental physical and biological sciences, and the computer skills needed for the practice of agricultural and biosystems engineering.
Practice design skills, including the ability to think creatively, to formulate problem statements, to communicate effectively, to synthesize information, and to evaluate and implement problem solutions both individually and in team settings.
Address issues of ethics, safety, professionalism, diversity, globalization, environmental impact, and social and economic impact in engineering practice.
Contribute to agricultural profitability and enhance environmental and biological systems through the development, adaptation, and proper use of improved and safer engineering technologies, production systems, and management practices.

Student Outcomes

Graduates of the Agricultural and Biosystems Engineering program will have:

An ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics.
an ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors.
An ability to communicate effectively with a range of audiences.
An ability to 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.
An ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
An ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
An ability to acquire and apply new knowledge as needed, using appropriate learning strategies.

Accreditation, Certification, and Licensure

The Agricultural and Biosystems Engineering (B.S.) program at SDSU is accredited by the Engineering Accreditation Commission of ABET, https://www.abet.org.

The Fundamentals of Engineering examination is a national licensure examination that covers material taught in an ABET-accredited engineering program. Completion of the exam prior to graduation is a requirement for the B.S. in Agricultural and Biosystems Engineering program and required for any engineering graduate who wishes to become licensed as a Professional Engineer.

Course Delivery Format

The ABE program engages students in lecture, laboratory, and field based learning experiences. Senior students are members of design teams which design, build, test and demonstrate engineered products and processes.

Requirements for Agricultural and Biosystems Engineering Major: 130 Credits

Bachelor of Science

System General Education Requirements

Goal #1 Written Communication: ENGL 101 - Composition I (COM) [SGR #1] Credits: 3 and ENGL 277 - Technical Writing in Engineering [SGR #1] Credits: 3 ¹
Goal #2 Oral Communication: CMST 101 - Fundamentals of Speech (COM) [SGR #2] Credits: 3
Goal #3 Social Sciences/Diversity: SGR #3 Electives Credits: 6
Goal #4 Arts and Humanities/Diversity: SGR #4 Electives Credits: 6
Goal #5 Mathematics: MATH 123 - Calculus I (COM) [SGR #5] Credits: 4
Goal #6 Natural Sciences: PHYS 211 - University Physics I (COM) [SGR #6] Credits: 4 , PHYS 211L - University Physics I Lab (COM) [SGR #6] Credits: 0 , PHYS 213 - University Physics II (COM) [SGR #6] Credits: 4 , and PHYS 213L - University Physics II Lab (COM) [SGR #6] Credits: 0

Major Requirements

ABE 101 - Introduction to Agricultural and Biosystems Engineering Credits: 1
ABE 132 - Engineering Tools for Agricultural and Biological Engineers Credits: 1
ABE 222 - Project Development for Agricultural and Biological Engineers Credits: 1
ABE 314 - Ag Power and Machines Credits: 4 ³
ABE 314L - Ag Power and Machines Lab Credits: 0
ABE 324 - Ag Structures and Indoor Environment Credits: 4 ³
ABE 324L - Ag Structures and Indoor Environment Lab Credits: 0
ABE 343 - Engineering Properties of Biological Materials Credits: 3
ABE 343L - Engineering Properties of Biological Materials Lab Credits: 0
ABE 411 - Design Project III Credits: 2
ABE 422 - Design Project IV Credits: 2
ABE 434 - Natural Resources Engineering Credits: 4 ³
ABE 434L - Natural Resources Engineering Lab Credits: 0
ABE 444 - Unit Operations of Biological Materials Processing Credits: 4 ³
ABE 444L - Unit Operations of Biological Materials Processing Lab Credits: 0
ABE 463 - Instrumentation for Agricultural and Biological Systems Credits: 3
ABE 463L - Instrumentation for Agricultural and Biological Systems Lab Credits: 0
ABE 464 - Monitoring and Controlling Agriculture and Biological Systems Credits: 2
ABE 464L - Monitoring and Controlling Agriculture and Biological Systems Lab Credits: 0
ABE 494 - Internship (COM) Credits: 1-6 (2 credits required)
or ABE 496 - Field Experience (COM) Credits: 1-6 (2 credits required)
or ABE 498 - Undergraduate Research/Scholarship (COM) Credits: 1-3 (2 credits required)
BIOL 103 - Biology Survey II (COM) [SGR #6] Credits: 2
BIOL 103L - Biology Survey II Lab (COM) [SGR #6] Credits: 1
CHEM 108 - Organic and Biochemistry (COM) [SGR #6] Credits: 4
CHEM 108L - Organic and Biochemistry Lab (COM) [SGR #6] Credits: 1
CHEM 112 - General Chemistry I (COM) [SGR #6] Credits: 3
CHEM 112L - General Chemistry I Lab (COM) [SGR #6] Credits: 1
CSC 130 - Visual Basic Programming (COM) Credits: 3
or CSC 150 - Computer Science I (COM) Credits: 3
EE 300 - Basic Electrical Engineering I Credits: 2
EE 300L - Basic Electrical Engineering I Lab Credits: 1
EM 214 - Statics (COM) Credits: 3
EM 215 - Dynamics Credits: 3
EM 321 - Mechanics of Materials (COM) Credits: 3
EM 331 - Fluid Mechanics (COM) Credits: 3
GE 101 - Introduction to Engineering and Technical Professions Credits: 1
GE 121 - Engineering Design Graphics I Credits: 1
GE 123 - Computer Aided Drawing Credits: 1
MATH 125 - Calculus II (COM) [SGR #5] Credits: 4
MATH 225 - Calculus III (COM) [SGR #5] Credits: 4
MATH 321 - Differential Equations (COM) Credits: 3
MATH 331 - Advanced Engineering Mathematics (COM) Credits: 3
or STAT 281 - Introduction to Statistics (COM) [SGR #5] Credits: 3
or STAT 381 - Introduction to Probability and Statistics (COM) Credits: 3
ME 314 - Thermodynamics Credits: 3

Technical Electives

The electives for each student must be approved by the advisor and will include 14 credit hours of technical electives, at least 6 credits from 300 or above level courses in the College of Engineering. Credits: 14

ABE 491 - Independent Study (COM) Credits: 1-3
ABE 492 - Topics (COM) Credits: 1-4
ABE 494 - Internship (COM) Credits: 1-6
ABE 496 - Field Experience (COM) Credits: 1-6
ABE 497 - Cooperative Education (COM) Credits: 1-6
CEE 225 - Principles of Environmental Science and Engineering Credits: 3
CSC 314 - Assembly Language (COM) Credits: 3
CSC 317 - Computer Organization and Architecture (COM) Credits: 3
EE 422 - Engineering Economics and Management Credits: 2 ²
GE 210 - Geometric Dimensioning and Tolerancing Credits: 2
GEOG 372 - Introduction to GIS (COM) Credits: 3
GEOG 372L - Introduction to GIS Lab (COM) Credits: 0
MATH 331 - Advanced Engineering Mathematics (COM) Credits: 3
MNET 220 - Parametric Modeling and Design Credits: 3
MNET 220L - Parametric Modeling and Design Lab Credits: 0
PRAG 340 - Climate Risk Management with Precision Agriculture Credits: 3
PRAG 410 - Soil Geography and Land Use Interpretation Credits: 2
PRAG 410L - Soil Geography and Land Use Interpretation Lab Credits: 1
STAT 281 - Introduction to Statistics (COM) [SGR #5] Credits: 3

Total Required Credits: 130

Curriculum Notes

¹Required to receive a “C” or better in ENGL 277.
²Technical elective credit not given for both CEE/CM 482 and EE 422.
³Students must take these courses, with the exception that they may choose to replace one of these four Agricultural and Biosystems Engineering courses with four additional technical elective credits (300 or higher in the College of Engineering) in addition to the basic technical elective requirements.

Summary of Program Requirements

Bachelor of Science
System General Education Requirements	33 Credit Hours
Major Requirements	83 Credit Hours
Electives**	14 Credit Hours

**Taken as needed to complete any additional degree requirements.

Academic Advising Guide Sheet

The goal of the academic advising guide sheets and sample plans of study is to promote undergraduate student success by guiding all students to timely completion of an undergraduate degree. Students are not limited to the course sequence provided for their academic program. Instead, the sample plan of study is one possible path to completing your degree and is meant to be used as a guide for planning purposes in consultation with an academic advisor. The plans also help students prepare for meetings with their academic advisor and track their progress in their selected academic program.