For the undergraduate curriculum in biological systems engineering leading to the degree bachelor of science. The Biological Systems Engineering program is accredited by the Engineering Accreditation Commission of ABET, http://www.abet.org/.
Biological Systems Engineering integrates life sciences with engineering to solve problems related to, or using, biological systems. These biological systems may include microbes, plants, animals, humans and/or ecosystems. Biological systems engineers have a worldview shaped by an understanding of fundamental principles of engineering and life-sciences. They use their understanding of engineering to analyze organisms or ecosystems, and their knowledge of biological systems to inspire and inform their designs. They approach engineering design from a biological systems perspective, appreciating the complexity of biological systems and developing solutions that accommodate and anticipate the adaptability of biological systems.
Goal: To educate students to solve problems related to biorenewables production and processing, water quality, environmental impacts of the bioeconomy, food processing, and biosensors, and in so doing to prepare students for professional practice and post-graduate educational opportunities.
Program Educational Objectives: Three to five years after graduation, our graduates will be using the knowledge, skills, and abilities from their biological systems engineering degree to improve the human condition through successful careers in a wide variety of fields. They will be effective leaders, collaborators, and innovators who address environmental, social, technical, and business challenges. They will be engaged in life-long learning and professional development through self-study, continuing education, or graduate/professional school.
Well-qualified juniors and seniors in biological systems engineering who are interested in graduate study may apply for concurrent enrollment in the Graduate College to simultaneously pursue a bachelor of science degree in biological systems engineering and a master of science degree in agricultural engineering. Under concurrent enrollment, students are eligible for assistantships and simultaneously take undergraduate and graduate courses.
A concurrent bachelor of science and master of business administration program is also offered by the department.
The department also offers a bachelor of science curriculum in agricultural engineering. See College of Engineering. Additionally, the department offers bachelor of science curricula in agricultural systems technology and in industrial technology. See College of Agriculture and Life Sciences.
The department also participates in interdepartmental majors in environmental science, sustainable agriculture, biorenewable resources and technology, human computer interaction, and toxicology (see Index).
Curriculum in Biological Systems Engineering
Administered by the Department of Agricultural and Biosystems Engineering.
Leading to the degree bachelor of science.
Total credits required:
128.0 cr Biorenewable Resources Option
127.0 cr Bioenvironmental Engineering Option
128.0 cr Food Engineering Option
128.0 cr Open Option.
Any transfer credit courses applied to the degree program require a grade of C or better (but will not be calculated into the ISU cumulative GPA, Basic Program GPA or Core GPA). See also Basic Program and Special Programs.
International Perspectives: 3 cr.1
U.S. Diversity: 3 cr.1
Communication Proficiency/Library requirement:
(Minimum GPA of 2.00 in this set of courses.)
ENGL 150 | Critical Thinking and Communication (Must have a C or better in this course) | 3 |
ENGL 250 | Written, Oral, Visual, and Electronic Composition (Must have a C or better in this course) | 3 |
LIB 160 | Information Literacy | 1 |
Communication Elective: One of the following (Must have a C or better in this course) | 3 | |
Presentation and Sales Strategies for Agricultural Audiences | ||
Proposal and Report Writing | ||
Technical Communication | ||
Advanced Professional Selling | ||
Fundamentals of Public Speaking |
Social Sciences and Humanities: 12 cr. 1,2
3 credits from international perspectives-university approved list | 3 | |
3 credits from U.S. diversity-university approved list | 3 | |
6 credits from Social Sciences and Humanities courses-department approved list | 6 | |
Total Credits | 12 |
Basic Program: 27 cr.
A minimum GPA of 2.00 required for this set of courses, including any transfer courses (please note that transfer course grades will not be calculated into the Basic Program GPA). See Requirement for Entry into Professional Program in College of Engineering Overview section. Within the Biological Systems Engineering Basic Program, students are required to complete CHEM 167 and CHEM 167L or the sequence of CHEM 177, CHEM 177L, and CHEM 178. This is a departmental requirement within the College of Engineering Basic Program requirements. The CHEM 178 course will show as completing the chemistry portion of the Basic Program and the credits will be applied towards a student's classification.
A B E 160 | Systematic Problem Solving and Computer Programming 3 | 3 |
CHEM 167 | General Chemistry for Engineering Students | 4 |
ENGL 150 | Critical Thinking and Communication (Must have a C or better in this course) | 3 |
ENGL 250 | Written, Oral, Visual, and Electronic Composition (Must have a C or better in this course) | 3 |
ENGR 101 | Engineering Orientation | R |
LIB 160 | Information Literacy | 1 |
MATH 165 | Calculus I | 4 |
MATH 166 | Calculus II | 4 |
PHYS 221 | Introduction to Classical Physics I | 5 |
Total Credits | 27 |
Biological, Math and Physical Science: 23 cr.
BIOL 212 | Principles of Biology II | 3 |
CHEM 167L | Laboratory in General Chemistry for Engineering | 1 |
or CHEM 177L | Laboratory in General Chemistry I | |
Chemistry Sequence I (select from list of lecture with corresponding lab) | 4 | |
Elementary Organic Chemistry | ||
Laboratory in Elementary Organic Chemistry | ||
Organic Chemistry I | ||
Laboratory in Organic Chemistry I | ||
MATH 267 | Elementary Differential Equations and Laplace Transforms | 4 |
MICRO 302 | Biology of Microorganisms | 3 |
MICRO 302L | Microbiology Laboratory | 1 |
STAT 305 | Engineering Statistics (Chemistry Sequence I) | 3 |
Chemistry Sequence II (select from list of lecture with corresponding lab) | 4 | |
Quantitative and Environmental Analysis | ||
Quantitative and Environmental Analysis Laboratory | ||
Organic Chemistry II | ||
Laboratory in Organic Chemistry II | ||
Food Chemistry | ||
Food Chemistry Laboratory | ||
Total Credits | 23 |
Biological Systems Engineering Core: 45 cr.
(A minimum GPA of 2.00 required for this set of courses, including any transfer courses; please note that transfer course grades will not be calculated into the Core GPA).
A B E 216 | Fundamentals of Agricultural and Biosystems Engineering | 3 |
A B E 218 | Project Management & Design in Agricultural and Biosystems Engineering | 2 |
A B E 273 | CAD for Process Facilities and Land Use Planning | 1 |
A B E 316 | Applied Numerical Methods for Agricultural and Biosystems Engineering | 3 |
A B E 363 | Agri-Industrial Applications of Electric Power and Electronics | 4 |
A B E 380 | Principles of Biological Systems Engineering | 3 |
A B E 404 | Instrumentation for Agricultural and Biosystems Engineering | 3 |
A B E 415 | Agricultural & Biosystems Engineering Design I | 2 |
A B E 416 | Agricultural & Biosystems Engineering Design II | 2 |
A B E 451 | Food and Bioprocess Engineering | 3 |
A B E 480 | Engineering Analysis of Biological Systems | 3 |
E M 274 | Engineering Statics | 3 |
E M 324 | Mechanics of Materials | 3 |
E M 327 | Mechanics of Materials Laboratory | 1 |
E M 378 | Mechanics of Fluids | 3 |
I E 305 | Engineering Economic Analysis | 3 |
M E 231 | Engineering Thermodynamics I | 3 |
Total Credits | 45 |
Other Remaining Courses: 8 cr.
A B E 110 | Experiencing Agricultural and Biosystems Engineering | 1 |
A B E 170 | Engineering Graphics and Introductory Design | 3 |
A B E 201 | Preparing for Workplace Seminar | 1 |
Communication Elective: One of the following (Must have a C or better in this course) | 3 | |
Presentation and Sales Strategies for Agricultural Audiences | ||
Proposal and Report Writing | ||
Technical Communication | ||
Advanced Professional Selling | ||
Fundamentals of Public Speaking | ||
Total Credits | 8 |
Complete remaining courses from one of the following options:
Biorenewable Resources Engineering Option: 13cr.
A B E 325 | Biorenewable Systems | 3 |
A B E 469 | Engineering for Grain Storage, Preservation, Handling, and Processing Systems | 3 |
M E 436 | Heat Transfer | 4 |
Biorenewable Elective (select 3cr from the following): | 3 | |
Supply Chain Management | ||
Food Processing | ||
Total Credits | 13 |
Bioenvironmental Engineering Option: 12 cr.
A B E 431 | Design and Evaluation of Soil and Water Conservation Systems | 3 |
C E 326 | Principles of Environmental Engineering | 3 |
C E 372 | Engineering Hydrology and Hydraulics | 3 |
Bioenvironmental Elective 2 | 3 | |
Total Credits | 12 |
Food Engineering Option: 13 cr.
A B E 469 | Engineering for Grain Storage, Preservation, Handling, and Processing Systems | 3 |
FS HN 420 | Food Microbiology | 3 |
M E 436 | Heat Transfer | 4 |
Food Elective (select 3cr from the following): | 3 | |
Food Processing | ||
Supply Chain Management | ||
Total Credits | 13 |
Open Option: 13 cr.
M E 436 | Heat Transfer | 4 |
Sequence I, II & III Elective 2 | 9 | |
Total Credits | 13 |
Co-op/Internships (Optional)
- These university requirements will add to the minimum credits of the program unless the university-approved courses are also approved by the department to meet other course requirements within the degree program.
U.S. Diversity, International Perspectives and Social Science/Humanities courses may not be taken Pass/Not Pass. - Choose from department approved list.
- See Basic Program for Professional Engineering Curricula for accepted substitutions for curriculum designated courses in the Basic Program.
Biological Systems Engineering, B.S. - bioenvironmental engr option
First Year | |||
---|---|---|---|
Fall | Credits | Spring | Credits |
ENGR 101 | R | A B E 110 | 1 |
A B E 170 | 3 | A B E 160 | 3 |
CHEM 167 | 4 | MATH 166 | 4 |
CHEM 167L | 1 | PHYS 221 | 5 |
MATH 165 | 4 | ENGL 250 | 3 |
ENGL 150 | 3 | ||
LIB 160 | 1 | ||
16 | 16 | ||
Second Year | |||
Fall | Credits | Spring | Credits |
A B E 216 | 3 | A B E 218 | 2 |
E M 274 | 3 | A B E 201 | 1 |
BIOL 212 | 3 | A B E 273 | 1 |
Chemistry Sequence I with Lab | 4 | M E 231 | 3 |
US Diversity Elective | 3 | MATH 267 | 4 |
Chemistry Sequence II with Lab | 4 | ||
16 | 15 | ||
Third Year | |||
Fall | Credits | Spring | Credits |
A B E 316 | 3 | A B E 363 | 4 |
E M 378 | 3 | A B E 380 | 3 |
MICRO 302 | 3 | C E 372 | 3 |
MICRO 302L | 1 | E M 324 | 3 |
STAT 305 | 3 | I E 305 | 3 |
International Perspective Elective | 3 | ||
16 | 16 | ||
Fourth Year | |||
Fall | Credits | Spring | Credits |
A B E 415 | 2 | A B E 416 | 2 |
A B E 404 | 3 | A B E 451 | 3 |
A B E 431 | 3 | C E 326 | 3 |
A B E 480 | 3 | E M 327 | 1 |
Communication Elective | 3 | Bioenvironmental Elective | 3 |
Social Science or Humanities Elective | 3 | Social Science or Humanities Elective | 3 |
17 | 15 |
Biological Systems Engineering, B.S. - biorenewable resources engr option
First Year | |||
---|---|---|---|
Fall | Credits | Spring | Credits |
ENGR 101 | R | A B E 110 | 1 |
A B E 170 | 3 | A B E 160 | 3 |
CHEM 167 | 4 | MATH 166 | 4 |
CHEM 167L | 1 | PHYS 221 | 5 |
MATH 165 | 4 | ENGL 250 | 3 |
ENGL 150 | 3 | ||
LIB 160 | 1 | ||
16 | 16 | ||
Second Year | |||
Fall | Credits | Spring | Credits |
A B E 216 | 3 | A B E 218 | 2 |
E M 274 | 3 | A B E 201 | 1 |
BIOL 212 | 3 | A B E 273 | 1 |
Chemistry Sequence I with Lab | 4 | M E 231 | 3 |
US Diversity Elective | 3 | MATH 267 | 4 |
Chemistry Sequence II with Lab | 4 | ||
16 | 15 | ||
Third Year | |||
Fall | Credits | Spring | Credits |
A B E 316 | 3 | A B E 363 | 4 |
A B E 325 | 3 | A B E 380 | 3 |
E M 378 | 3 | E M 324 | 3 |
MICRO 302 | 3 | I E 305 | 3 |
MICRO 302L | 1 | International Perspective | 3 |
STAT 305 | 3 | ||
16 | 16 | ||
Fourth Year | |||
Fall | Credits | Spring | Credits |
A B E 415 | 2 | A B E 416 | 2 |
A B E 404 | 3 | A B E 451 | 3 |
A B E 480 | 3 | A B E 469 | 3 |
Biorenewable Elective | 3 | E M 327 | 1 |
Social Science or Humanities Elective | 3 | M E 436 | 4 |
Communication Elective | 3 | Social Science or Humanities Elective | 3 |
17 | 16 |
Biological Systems Engineering, B.S. - Open Option
First Year | |||
---|---|---|---|
Fall | Credits | Spring | Credits |
ENGR 101 | R | A B E 110 | 1 |
A B E 170 | 3 | A B E 160 | 3 |
CHEM 167 | 4 | MATH 166 | 4 |
CHEM 167L | 1 | PHYS 221 | 5 |
MATH 165 | 4 | ENGL 250 | 3 |
ENGL 150 | 3 | ||
LIB 160 | 1 | ||
16 | 16 | ||
Second Year | |||
Fall | Credits | Spring | Credits |
A B E 216 | 3 | A B E 218 | 2 |
E M 274 | 3 | A B E 201 | 1 |
BIOL 212 | 3 | A B E 273 | 1 |
Chemistry Sequence I with lab | 4 | M E 231 | 3 |
US Diversity Elective | 3 | MATH 267 | 4 |
Chemistry Sequence II with Lab | 4 | ||
16 | 15 | ||
Third Year | |||
Fall | Credits | Spring | Credits |
A B E 316 | 3 | A B E 363 | 4 |
E M 378 | 3 | A B E 380 | 3 |
MICRO 302 | 3 | E M 324 | 3 |
MICRO 302L | 1 | I E 305 | 3 |
STAT 305 | 3 | Sequence I Elective | 3 |
International Perspective Elective | 3 | ||
16 | 16 | ||
Fourth Year | |||
Fall | Credits | Spring | Credits |
A B E 415 | 2 | A B E 416 | 2 |
A B E 404 | 3 | A B E 451 | 3 |
A B E 480 | 3 | E M 327 | 1 |
Sequence II Elective | 3 | M E 436 | 4 |
Communication Elective | 3 | Sequence III Elective | 3 |
Social Science or Humanities Elective | 3 | Social Science or Humanities Elective | 3 |
17 | 16 |
Biological Systems Engineering, B.S. Food Engineering Option
First Year | |||
---|---|---|---|
Fall | Credits | Spring | Credits |
ENGR 101 | R | A B E 110 | 1 |
A B E 170 | 3 | A B E 160 | 3 |
MATH 165 | 4 | MATH 166 | 4 |
CHEM 167 | 4 | PHYS 221 | 5 |
CHEM 167L | 1 | ENGL 250 | 3 |
ENGL 150 | 3 | ||
LIB 160 | 1 | ||
16 | 16 | ||
Second Year | |||
Fall | Credits | Spring | Credits |
A B E 216 | 3 | A B E 218 | 2 |
E M 274 | 3 | A B E 201 | 1 |
Chemistry Sequence I with Lab | 4 | A B E 273 | 1 |
BIOL 212 | 3 | M E 231 | 3 |
US Diversity Elective | 3 | MATH 267 | 4 |
Chemistry Sequence II with Lab | 4 | ||
16 | 15 | ||
Third Year | |||
Fall | Credits | Spring | Credits |
A B E 316 | 3 | A B E 363 | 4 |
E M 378 | 3 | A B E 380 | 3 |
MICRO 302 | 3 | A B E 469 | 3 |
MICRO 302L | 1 | E M 324 | 3 |
STAT 305 | 3 | I E 305 | 3 |
International Perspective Elective | 3 | ||
16 | 16 | ||
Fourth Year | |||
Fall | Credits | Spring | Credits |
A B E 415 | 2 | A B E 416 | 2 |
A B E 404 | 3 | A B E 451 | 3 |
A B E 480 | 3 | E M 327 | 1 |
FS HN 420 | 3 | M E 436 | 4 |
Food Elective | 3 | Social Science or Humanities Elective | 3 |
Communication Elective | 3 | Social Science or Humanities Elective | 3 |
17 | 16 |
Graduate Study
The department offers master of science, master of engineering, and doctor of philosophy degrees with a major in agricultural and biosystems engineering. Within the agricultural and biosystems engineering major the student may specialize in advanced machinery engineering, animal production systems engineering, biological and process engineering, occupational safety engineering, or water and environmental stewardship engineering. Details on current research programs available at http://www.abe.iastate.edu/.
For the master of science program, at least 30 credits of acceptable graduate work must be completed with a minimum of 22 credits of course work; corresponding numbers for the master of engineering program are 32 and 27. For the doctor of philosophy degree, at least 72 credits of acceptable graduate work must be completed with a minimum of 42 credits of course work. All Ph.D. students must complete a teaching/extension experience prior to graduation.
The department also offers both master of science and doctor of philosophy degrees in industrial and agricultural technology.
Courses
Courses primarily for undergraduates:
Cr. 0.5. F.
8 week learning communities course focusing on student success, engineering, and department curriculum. Building community within the ABE Department.
Offered on a satisfactory-fail basis only.
(0-2) Cr. 1. S.
Laboratory-based, team-oriented experiences in a spectrum of topics common to the practice of agricultural and biosystems engineering. Report writing, co-ops, internships, careers, registration planning.
(2-2) Cr. 3. S.
Prereq: Credit or enrollment in MATH 143 or MATH 165
Engineering approach to problem solution and presentation in the context of real world problems. Introduction to basic principles from statics, projectile motion, conservation of mass and energy and electricity and magnetism. Use of spreadsheet programs and computer programming language(s) to solve and present engineering problems.
Only one of ENGR 160, A B E 160, AER E 160, C E 160, CH E 160, CPR E 185, EE 185, IE 148, M E 160 and S E 185 may count towards graduation.
(2-2) Cr. 3.
Applications of multi-view drawings and dimensioning. Techniques for visualizing, analyzing, and communicating 3-D geometries. Application of the design process including written and oral reports.
(Cross-listed with TSM). (1-0) Cr. 1. F.S.
Prereq: Prereq: Sophomore classification in AE, AST, BSE, or I TEC
8 week course. Professionalism in the context of the engineering/technical workplace. Development and demonstration of key workplace competencies: teamwork, initiative, communication, and engineering/technical knowledge. Resumes; Cover Letters; Behavioral Based Interviewing; Industry Speakers; Preparation for internships experiences.
(2-2) Cr. 3. F.
Prereq: A B E 160 or permission of the instructor
Application of mathematics and engineering sciences to mass and energy balances in agricultural and biological systems. Emphasis is on solving engineering problems in the areas of heat and mass transfer, air and water vapor systems; animal production systems, grain systems; food systems, hydrologic systems, and bioprocessing.
(1-2) Cr. 2. S.
Prereq: A B E 216
Project management - critical path, Gantt charts, resource allocations, basic project budgeting, and project management software. Engineering design approaches. Open-ended design projects to demonstrate the preceding principles through application of technical concepts taught in prerequisite coursework.
(1-2) Cr. 1. F.S.
Prereq: A B E 170 or TSM 116 or equivalent
8 week-course. Applications of Creo Parametric software. Create solid models of parts and assemblies. Utilize the solid models to create design documentation (standard drawing views, dimensions, and notes) and for the geometric analysis of parts and assemblies.
(1-2) Cr. 1. F.S.
Prereq: ENGR 170 or TSM 116 or equivalent.
8-week course. Application of 2-D AutoCAD software to create and interpret 2-D drawings and 3-D models of facilities. Topics include geometric construction, design documentation: (using views, dimension, notes), and AutoCAD specific features (i.e. Layers, Blocks, Standards, Styles).
(Cross-listed with TSM). (3-0) Cr. 3. F.
Prereq: CHEM 163 or higher; MATH 140 or higher
Converting biorenewable resources into bioenergy and biobased products. Biorenewable concepts as they relate to drivers of change, feedstock production, processes, products, co-products, economics, and transportation/logistics.
(2-2) Cr. 3. F.
Prereq: A B E 216
Principles of machine systems operation (tillage, crop establishment, harvesting and crop protection). Principles of soil and crop interactions with machine systems. Experimental and simulation techniques for testing and evaluation of agricultural field machinery for equipment performance, functional analysis and crop production management.
(3-2) Cr. 4. F.S.
Prereq: A B E 216
Single phase and three phase circuit design. Electrical safety. Electric motors and controls. Programmable logic controllers. Digital logic, instrumentation and sensors.
(2-2) Cr. 3. S.
Prereq: A B E 316
Engineering analysis of biological systems, through the study of mass, energy, and information transport. Quantification and modeling of biological interactions, biological activities and bioreactor operations. Includes hands-on laboratory experiences.
(Cross-listed with C E, E E). (2-2) Cr. 3. F.
Prereq: Junior classification in engineering
Multi-disciplinary approach to sustainable engineering and international development, sustainable development, appropriate design and engineering, feasibility analysis, international aid, business development, philosophy and politics of technology, and ethics in engineering. Engineering-based projects from problem formulation through implementation. Interactions with partner community organizations or international partners such as nongovernment organizations (NGOs). Course readings, final project/design report.
Meets International Perspectives Requirement.
Cr. R. Repeatable. SS.
Prereq: Permission of department and Engineering Career Services
Professional work period of at least 10 weeks during the summer. Students must register for this course prior to commencing work.
Offered on a satisfactory-fail basis only.
Cr. R. Repeatable. F.S.
Prereq: A B E 218 and permission of department and Engineering Career Services
Professional work period. One semester per academic or calendar year. Students must register for this course before commencing work.
Offered on a satisfactory-fail basis only.
(Dual-listed with A B E 503). (2-2) Cr. 3. Alt. S., offered odd-numbered years.
Prereq: A B E 316, and A B E 363, and MATH 266 or MATH 267
Modeling dynamic systems with ordinary differential equations. Introduction to state variable methods of system analysis. Analysis of mechanical, electrical, and fluid power systems. Analytical and numerical solutions of differential equations. Introduction to classical control theory. Feedback and stability examined in the s domain. Frequency response as an analytical and experimental tool. MATLAB will be used throughout the course for modeling. Individual and/or group projects required for graduate credit.
(Dual-listed with A B E 504). (2-2) Cr. 3. F.
Prereq: A B E 316 and A B E 363
Interfacing techniques for computer-based data acquisition and control systems. Basic interfacing components including A/D and D/A conversion, signal filtering, multiplexing, and process control. Sensors and theory of operation applied to practical monitoring and control problems. Individual and group projects required for graduate credit.
(Dual-listed with A B E 510). Cr. 3. S.
System architecture and design of electronics used in agricultural machinery and production systems. Emphasis on information technology and systems integration for automated agriculture processes. Design of Controller Area Network (CAN BUS) communication systems and discussion of relevant standards (ISO 11783 and SAE J1939). Application of technologies for sensing, distribution control, and automation of agricultural machinery will be emphasized.
(Cross-listed with M E). (2-2) Cr. 3. F.
Prereq: Credit or enrollment in E M 378 or M E 335, A B E 216 or M E 270
Properties of hydraulic fluids. Performance parameters of fixed and variable displacement pumps and motors. Hydraulic circuits and systems. Hydrostatic transmissions. Characteristics of control valves. Analysis and design of hydraulic systems for power and control functions.
(1-2) Cr. 2. F.S.
Prereq: A B E 316 (majors only)
Identification of current design problems in ag & biosystems engineering. Development of alternate solutions using creativity and engineering analysis and synthesis techniques.
(1-2) Cr. 2. F.S.
Prereq: A B E 415 (majors only)
Selection of promising solutions to design problems identified in 415 for development by design teams. Presentation of designs through oral and written reports and prototypes.
(1-0) Cr. 1.
Prereq: senior classification.
8 week course. Review of core concepts covered in the Fundamentals of Engineering examination with emphasis on statics, dynamics, fluid mechanics, heat transfer, electric circuits, and engineering economics. Open to all College of Engineering seniors, however focus is on the general exam, not discipline specific exams.
(Dual-listed with A B E 531). (2-3) Cr. 3. F.
Prereq: E M 378 or CH E 356
Hydrology and hydraulics in agricultural and urbanizing watersheds. Design and evaluation of systems for the conservation and quality preservation of soil and water resources. Use and analysis of hydrologic data in engineering design; relationship of topography, soils, crops, climate, and cultural practices in conservation and quality preservation of soil and water for agriculture. Small watershed hydrology, water movement and utilization in the soil-plant-atmosphere system, agricultural water management, best management practices, and agricultural water quality. Graduate students will prepare several research literature reviews on topics covered in the class in addition to the other assignments.
(Dual-listed with A B E 532). (3-0) Cr. 3.
Prereq: A B E 431 or C E 372
Characteristics and courses of non-point source (NPS) pollution in agricultural and urban watersheds, computer modeling and NPS pollution for terrestrial and aquatic systems, strategies to control and manage NPS pollution of water bodies, total maximum daily loads (TMDLs) and integrated watershed management. Graduate students are required to review research papers and develop/deliver lecture models on assigned topics.
(Dual-listed with A B E 536). (2-3) Cr. 3. Alt. S., offered even-numbered years.
Prereq: A B E 431
Development of monitoring systems that support effective planning, performance evaluation, modeling, or environmental impact assessment of soil-, water-, and waste-management systems. Typical soil and water pollutants and physical, chemical, and biological characteristics that affect sample location and timing. Sample collection, documentation, chain-of-custody, and quality assurance procedures. In addition to other assignments, graduate students will prepare several research literature reviews on topics covered in the class and develop monitoring plans.
(Dual-listed with A B E 537). (Cross-listed with ENSCI). (2-2) Cr. 3. Alt. F., offered odd-numbered years.
Prereq: CE 372 or equivalent
A project-based course on watershed-scale models for improving water quality. Legislative and judicial basis of the Total Maximum Daily Load (TMDL) program; approaches to TMDL development; principles and techniques for implementation; stakeholder engagement strategies. Hands-on experiences with GIS-interfaced models, data sources, calibration/validation, statistical assessment of model results, and simulation using multiple tools. In addition to other assignments, graduate students will present case studies of TMDLs using different modeling tools.
(Dual-listed with A B E 551). (3-0) Cr. 3. S.
Prereq: A B E 216 and credit or enrollment in M E 436 or CH E 357; or FS HN 351 and MATH 266 or MATH 267
Application of engineering principles and mathematical modeling to the quantitative analysis of food and bioprocessing systems. Physical/chemical characteristics of foods and biological systems, flow processes, thermal processes and separation processes. Term paper required for graduate credit.
(Cross-listed with AER E, B M E, CPR E, E E, ENGR, I E, M E, MAT E). (1-4) Cr. 3. Repeatable. F.S.
Prereq: Student must be within two semesters of graduation; permission of instructor.
Application of team design concepts to projects of a multidisciplinary nature. Concurrent treatment of design, manufacturing, and life cycle considerations. Application of design tools such as CAD, CAM, and FEM. Design methodologies, project scheduling, cost estimating, quality control, manufacturing processes. Development of a prototype and appropriate documentation in the form of written reports, oral presentations and computer models and engineering drawings.
(Dual-listed with A B E 569). (2-3) Cr. 3. S.
Prereq: A B E 216
Cereal grain and oilseed production, properties, and quality assessment. Design of storage systems, drying systems, material handling, and size reduction systems. Design of cereal grain processing systems, including dry milling, wet milling, flour milling, feed milling, and fermentation facilities.
(Dual-listed with A B E 572). (3-0) Cr. 3. Alt. S., offered even-numbered years.
Prereq: A B E 216, M E 231
Principles and design of animal environmental control systems. Insulation, heat and mass transfer, fans, ventilation, air distribution, heating and cooling equipment, and controls. Individual and group projects required for graduate credit.
(2-0) Cr. 2. F.S.
Prereq: A B E 271, A B E 272, or A B E 273; E M 324 and enrollment in APSE option of AE program.
Application of engineering fundamentals to the independent solution of an animal production systems engineering problem with well defined criteria and constraints in either environmental control, structural design, manure management, or air quality/mitigation.
(Dual-listed with A B E 578). (3-0) Cr. 3. Alt. S., offered odd-numbered years.
Prereq: M E 231, E M 324
Design of light-framed wood structures using LRFD and ASD design procedures. Includes analysis of wind, snow, dead, and live loads. Applications include animal housing and machine storage. Fasteners, laminated posts, truss design and use of National Design Specifications.
(Dual-listed with A B E 580). (Cross-listed with ENSCI). (2-2) Cr. 3. F.
Prereq: A B E 380 or permission of the instructor
Systems-level quantitative analysis of biological systems, including applications in foods, feeds, biofuels, bioenergy, and other biological systems. Introduction to economic analysis and life-cycle assessment of these systems at multiple production scales. Applying these tools to evaluate and improve cost and sustainability performance of these biological systems. Students enrolled in ABE 580 will be required to answer additional exam questions and report on two journal articles.
Cr. 1-5. Repeatable.
Independent Study.
Cr. 1-5. Repeatable.
Independent Study.
Cr. 1-5. Repeatable. F.S.SS.
Independent study.
Cr. 1-5. Repeatable. F.S.SS.
Independent study in environmental bioprocessing engineering.
Cr. 1-5. Repeatable. F.S.SS.
Independent study in food engineering.
Cr. 1-5. Repeatable. F.S.SS.
Independent study in general A B E topics.
Cr. 1-5. Repeatable.
Guided instructing in agricultural and biosystems engineering for honors students.
Cr. 1-5. Repeatable.
Guided instruction in land and water resources engineering.
Cr. 1-5. Repeatable.
Guided instruction in advance machinery systems engineering.
(Cross-listed with TSM). Cr. 1-2. Repeatable. F.S.SS.
Prereq: Permission of instructor
Preparation for, or follow-up of, study abroad experience (496). For preparation, course focuses on understanding the tour destination through readings, discussions, and research on topics such as the regional industries, climate, crops, culture, economics, food, geography, government, history, natural resources, and public policies. For follow-up, course focuses on presentations by students, report writing, and reflection. Students enrolled in this course intend to register for 496 the following term or have had taken 496 the previous term.
Meets International Perspectives Requirement.
(Cross-listed with TSM). Cr. 1-4. Repeatable. F.S.SS.
Prereq: Permission of instructor
Tour and study at international sites relevant to disciplines of industrial technology, biological systems engineering, agricultural systems technology, and agricultural engineering. Location and duration of tours will vary. Trip expenses paid by students. Pre-trip preparation and/or post-trip reflection and reports arranged through 495.
Meets International Perspectives Requirement.
Courses primarily for graduate students, open to qualified undergraduates:
(Dual-listed with A B E 403). (2-2) Cr. 3. Alt. S., offered odd-numbered years.
Prereq: A B E 316, and A B E 363, and MATH 266 or MATH 267
Modeling dynamic systems with ordinary differential equations. Introduction to state variable methods of system analysis. Analysis of mechanical, electrical, and fluid power systems. Analytical and numerical solutions of differential equations. Introduction to classical control theory. Feedback and stability examined in the s domain. Frequency response as an analytical and experimental tool. MATLAB will be used throughout the course for modeling. Individual and/or group projects required for graduate credit.
(Dual-listed with A B E 404). (2-2) Cr. 3. F.
Prereq: A B E 316 and A B E 363
Interfacing techniques for computer-based data acquisition and control systems. Basic interfacing components including A/D and D/A conversion, signal filtering, multiplexing, and process control. Sensors and theory of operation applied to practical monitoring and control problems. Individual and group projects required for graduate credit.
(2-2) Cr. 3. Alt. F., offered even-numbered years.
Prereq: A B E 316 or equivalent, MATH 166, STAT 305
Applications of biologically inspired computational intelligence tools for data mining, system modeling, and optimization for agricultural, biological and other engineered systems. Introduction to Artificial Neural Networks, Support Vector Machines, Fuzzy Logic, Genetic Algorithms, Bayesian and Decision Tree learning. Fundamental Machine Vision techniques will be introduced in the first part of course and be integrated into the lab exercises for learning different computational intelligence techniques. MATLAB will be used throughout the course for algorithm implementation.
(Dual-listed with A B E 410). Cr. 3. S.
System architecture and design of electronics used in agricultural machinery and production systems. Emphasis on information technology and systems integration for automated agriculture processes. Design of Controller Area Network (CAN BUS) communication systems and discussion of relevant standards (ISO 11783 and SAE J1939). Application of technologies for sensing, distribution control, and automation of agricultural machinery will be emphasized.
(3-0) Cr. 3. F.
Prereq: A B E 216 or equivalent, MATH 160 or MATH 165, one of CHEM 167 or higher, BIOL 173 or BIOL 211 or higher or BRT 501, senior or graduate classification
Sustainability, cleaner production. Taxonomy, kinetics, metabolism, aerobic and anaerobic fermentation. Biofuels, bioenergy and coproducts. Mass/energy balances, process integration, pretreatment, separation. Membrane reactors, bioelectrolysis, microbial fuel cells, nanotechnology, genetic engineering, mutagenesis. Term paper for graduate level only.
(Cross-listed with AGRON, AN S, SUSAG). (3-0) Cr. 3. Alt. F., offered odd-numbered years.
Prereq: SUSAG 509
Methods to maintain productivity and minimize the negative ecological effects of agricultural systems by understanding nutrient cycles, managing manure and crop residue, and utilizing multispecies interactions. Crop and livestock production within landscapes and watersheds is also considered. Course includes a significant field component, with student teams analyzing Iowa farms.
(Dual-listed with A B E 431). (Cross-listed with ENSCI). (2-3) Cr. 3. F.
Prereq: E M 378 or CH E 356
Hydrology and hydraulics in agricultural and urbanizing watersheds. Design and evaluation of systems for the conservation and quality preservation of soil and water resources. Use and analysis of hydrologic data in engineering design; relationship of topography, soils, crops, climate, and cultural practices in conservation and quality preservation of soil and water for agriculture. Small watershed hydrology, water movement and utilization in the soil-plant-atmosphere system, agricultural water management, best management practices, and agricultural water quality. Graduate students will prepare several research literature reviews on topics covered in the class in addition to the other assignments.
(Dual-listed with A B E 432). (Cross-listed with ENSCI). (3-0) Cr. 3.
Prereq: A B E 431 or C E 372
Characteristics and courses of non-point source (NPS) pollution in agricultural and urban watersheds, computer modeling and NPS pollution for terrestrial and aquatic systems, strategies to control and manage NPS pollution of water bodies, total maximum daily loads (TMDLs) and integrated watershed management. Graduate students are required to review research papers and develop/deliver lecture models on assigned topics.
(Cross-listed with ENSCI, NREM). (2-3) Cr. 3. F.
Prereq: C E 372 or GEOL/ENSCI/MTEOR 402, MATH 166 or equivalent
Soil erosion processes, soil loss equations and their application to conservation planning, sediment properties, initiation of sediment motion and over land flow, flow in alluvial channels and theory of sediment transport, channel stability, reservoir sedimentation, wind erosion, BMPs for controlling erosion.
(Dual-listed with A B E 436). (Cross-listed with ENSCI). (2-3) Cr. 3. Alt. S., offered even-numbered years.
Prereq: A B E 431
Development of monitoring systems that support effective planning, performance evaluation, modeling, or environmental impact assessment of soil-, water-, and waste-management systems. Typical soil and water pollutants and physical, chemical, and biological characteristics that affect sample location and timing. Sample collection, documentation, chain-of-custody, and quality assurance procedures. In addition to other assignments, graduate students will prepare several research literature reviews on topics covered in the class and develop monitoring plans.
(Dual-listed with A B E 437). (Cross-listed with ENSCI). (2-2) Cr. 3. Alt. F., offered odd-numbered years.
Prereq: CE 372 or equivalent
A project-based course on watershed-scale models for improving water quality. Legislative and judicial basis of the Total Maximum Daily Load (TMDL) program; approaches to TMDL development; principles and techniques for implementation; stakeholder engagement strategies. Hands-on experiences with GIS-interfaced models, data sources, calibration/validation, statistical assessment of model results, and simulation using multiple tools. In addition to other assignments, graduate students will present case studies of TMDLs using different modeling tools.
(Dual-listed with A B E 451). (3-0) Cr. 3. S.
Prereq: A B E 216 and credit or enrollment in M E 436 or CH E 357; or FS HN 351 and MATH 266 or MATH 267
Application of engineering principles and mathematical modeling to the quantitative analysis of food and bioprocessing systems. Physical/chemical characteristics of foods and biological systems, flow processes, thermal processes and separation processes. Term paper required for graduate credit.
(Dual-listed with A B E 469). (2-3) Cr. 3. S.
Prereq: A B E 216
Cereal grain and oilseed production, properties, and quality assessment. Design of storage systems, drying systems, material handling, and size reduction systems. Design of cereal grain processing systems, including dry milling, wet milling, flour milling, feed milling, and fermentation facilities.
(Dual-listed with A B E 472). (3-0) Cr. 3. Alt. S., offered even-numbered years.
Prereq: A B E 216, M E 231
Principles and design of animal environmental control systems. Insulation, heat and mass transfer, fans, ventilation, air distribution, heating and cooling equipment, and controls. Individual and group projects required for graduate credit.
(Dual-listed with A B E 478). (3-0) Cr. 3. Alt. S., offered odd-numbered years.
Prereq: M E 231, E M 324
Design of light-framed wood structures using LRFD and ASD design procedures. Includes analysis of wind, snow, dead, and live loads. Applications include animal housing and machine storage. Fasteners, laminated posts, truss design and use of National Design Specifications.
(Dual-listed with A B E 480). (2-2) Cr. 3. F.
Prereq: A B E 380 or permission of the instructor
Systems-level quantitative analysis of biological systems, including applications in foods, feeds, biofuels, bioenergy, and other biological systems. Introduction to economic analysis and life-cycle assessment of these systems at multiple production scales. Applying these tools to evaluate and improve cost and sustainability performance of these biological systems. Students enrolled in ABE 580 will be required to answer additional exam questions and report on two journal articles.
Cr. 1-3. Repeatable.
Guided instruction and self-study on special topics relevant to agricultural and biosystems engineering.
Courses for graduate students:
(Cross-listed with TSM). (1-0) Cr. 1. F.
Keys to starting a successful graduate research project. Effective literature review, formulating research questions, and setting goals. Practicing effectively communicating research and science. Effective strategies for scholarly writing, responding to feedback, peer-reviewing, successful publishing in journals, and curating scholarly output.
(Cross-listed with AGRON, ANTHR, SOC, SUSAG). (3-0) Cr. 3. F.
Prereq: Graduate classification, permission of instructor
Historical, biophysical, socioeconomic, and ethical dimensions of agricultural sustainability. Strategies for evaluating existing and emerging agricultural systems in terms of the core concepts of sustainability and their theoretical contexts.
Cr. arr. Repeatable.
Advanced topics.
(Cross-listed with TSM). Cr. 1-3. Repeatable. F.S.
Prereq: Graduate classification and permission of instructor
Graduate student experience in the agricultural and biosystems engineering departmental teaching program.
Cr. R. Repeatable.
Prereq: Permission of department chair, graduate classification
One semester and one summer maximum per academic year professional work period.
Cr. arr. Repeatable.
Research.
Cr. arr. Repeatable.
Guided graduate research in biosystems engineering.
Cr. arr. Repeatable.
Guided graduate research in computer-aided design.
Cr. arr. Repeatable.
Guided graduate research in environmental systems.
Cr. arr. Repeatable.
Guided graduate research in food engineering.
Cr. arr. Repeatable.
Guided graduate research in occupational safety.
Cr. arr. Repeatable.
Guided graduate research in power and machinery engineering.
Cr. arr. Repeatable.
Guided graduate research in structures.
Cr. arr. Repeatable.
Guided graduate research in process engineering.
Cr. arr. Repeatable.
Guided graduate research in environment and natural resources.
Cr. arr. Repeatable.
Guided graduate research in waste management.