Subject: Engineering (UG) (ENGR)

CRN: 20246

In Person | Lecture

St Paul: In Person

Instructor: TBD

This course introduces students to the engineering disciplines and the design process through a semester-long design challenge. Students will gain improved self-awareness, empathy, and critical thinking skills; this will help them work as a team in a collaborative and inclusive environment to identify a need, interview clients, plan tasks and propose engineering solutions with consideration for the common good.

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20247

In Person | Lecture

St Paul: In Person

Instructor: TBD

This course introduces students to the engineering disciplines and the design process through a semester-long design challenge. Students will gain improved self-awareness, empathy, and critical thinking skills; this will help them work as a team in a collaborative and inclusive environment to identify a need, interview clients, plan tasks and propose engineering solutions with consideration for the common good.

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20107

In Person | Lecture

St Paul: In Person

Core Requirements Met:
     [Core] Natural Science

Other Requirements Met:
     School of Ed Transfer Course

Instructor: TBD

The course examines the core concepts of energy and power technologies. A hands-on laboratory will examine how refrigerators, swamp coolers, generators, turbines, car engines and solar panels work. The class covers how electricity from fossil fuels is generated and transported, and the status of the technology behind harnessing geothermal resources, solar power, fuel cells, wind power, and biomass energy. Students will be introduced to the 1st and 2nd laws of thermodynamics, trade-off charts and the design process. The cultural, social, and economic impacts of energy production are discussed as well as their effects on the environment. (This course is limited to non-majors or students with Freshman or Sophomore standing.)

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20109

In Person | Lab

St Paul: In Person

Core Requirements Met:
     [Core] Natural Science

Other Requirements Met:
     School of Ed Transfer Course

Instructor: TBD

The course examines the core concepts of energy and power technologies. A hands-on laboratory will examine how refrigerators, swamp coolers, generators, turbines, car engines and solar panels work. The class covers how electricity from fossil fuels is generated and transported, and the status of the technology behind harnessing geothermal resources, solar power, fuel cells, wind power, and biomass energy. Students will be introduced to the 1st and 2nd laws of thermodynamics, trade-off charts and the design process. The cultural, social, and economic impacts of energy production are discussed as well as their effects on the environment. (This course is limited to non-majors or students with Freshman or Sophomore standing.)

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20110

In Person | Lab

St Paul: In Person

Core Requirements Met:
     [Core] Natural Science

Other Requirements Met:
     School of Ed Transfer Course

Instructor: TBD

The course examines the core concepts of energy and power technologies. A hands-on laboratory will examine how refrigerators, swamp coolers, generators, turbines, car engines and solar panels work. The class covers how electricity from fossil fuels is generated and transported, and the status of the technology behind harnessing geothermal resources, solar power, fuel cells, wind power, and biomass energy. Students will be introduced to the 1st and 2nd laws of thermodynamics, trade-off charts and the design process. The cultural, social, and economic impacts of energy production are discussed as well as their effects on the environment. (This course is limited to non-majors or students with Freshman or Sophomore standing.)

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20248

In Person | Lecture

St Paul: In Person

Instructor: TBD

Through a combination of lectures, hands-on computer time, and design projects, students will learn to read, and create, engineering drawings and use computer-aided-design (CAD) terminology and technology. Topics covered will include the engineering design process, rapid prototyping, principles of projection, and introductory methods of representation and constructive geometry.

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20249

In Person | Lecture/Lab

St Paul: Schoenecker Center 309

  Andrew Tubesing

A hands-on introduction to a variety of basic concepts in Electrical and Computer Engineering. The course includes lessons, labs, and projects that explore analog and digital electronics in both theory and practice. Students will develop proficiency in the basic tools and skills required for electrical and computer engineering projects and coursework, and gain insight into them as a potential major, minor, and/or career.

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20036

In Person | Lecture

St Paul: In Person

Instructor: TBD

Principles of statics including such topics as rigid bodies, equilibrium, equivalent systems of forces, 2D structures, distributed forces, centroids and centers of gravity, moments of inertia, friction, forces in beams & cables, and the principle of virtual work. Emphasis on applications with integrated labs/hands-on projects. Prerequisites: A minimum grade of C- in PHYS 211 and a processed Engineering (Electrical, Computer, Civil, Mechanical) or Physics major or minor declaration.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20284

In Person | Lecture

St Paul: In Person

Instructor: TBD

Principles of statics including such topics as rigid bodies, equilibrium, equivalent systems of forces, 2D structures, distributed forces, centroids and centers of gravity, moments of inertia, friction, forces in beams & cables, and the principle of virtual work. Emphasis on applications with integrated labs/hands-on projects. Prerequisites: A minimum grade of C- in PHYS 211 and a processed Engineering (Electrical, Computer, Civil, Mechanical) or Physics major or minor declaration.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20001

In Person | Lecture

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20002

In Person | Lecture

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20117

In Person | Lecture

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20071

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20072

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20073

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20182

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20074

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20108

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of deformable body mechanics including stress, strain, basic loading situations, transformations of stress and strain, beam theory, and energy methods. Emphasis on applications with integrated labs/hands-on projects. Prerequisite: A minimum grade of C- in ENGR 220

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20042

In Person | Lecture

St Paul: Schoenecker Center 314

  Lucas Koerner

Introduction to the design of digital logic. Topics include Boolean logic, design and optimization of combinational and sequential logic, Hardware Description Language (HDL), the use of field-programmable devices (FPGAs), logic hazards, electronic implementation of logic gates. Students will be expected to specify, design, simulate, construct, and test digital circuits and document all phases of the process.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20043

In Person | Lab

St Paul: Schoenecker Center 309

Instructor: TBD

Introduction to the design of digital logic. Topics include Boolean logic, design and optimization of combinational and sequential logic, Hardware Description Language (HDL), the use of field-programmable devices (FPGAs), logic hazards, electronic implementation of logic gates. Students will be expected to specify, design, simulate, construct, and test digital circuits and document all phases of the process.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20044

In Person | Lab

St Paul: Schoenecker Center 309

Instructor: TBD

Introduction to the design of digital logic. Topics include Boolean logic, design and optimization of combinational and sequential logic, Hardware Description Language (HDL), the use of field-programmable devices (FPGAs), logic hazards, electronic implementation of logic gates. Students will be expected to specify, design, simulate, construct, and test digital circuits and document all phases of the process.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20003

In Person | Lecture

St Paul: Schoenecker Center 314

  Mohamed Moustafa

Introduction to analog electrical circuits in the time and frequency domains. Circuit analysis techniques including nodal analysis and equivalence theorems will be covered and used to assess a variety of circuits in the time and frequency domains. Students will develop analysis and laboratory skills to analyze and test the operation of circuits composed of resistors, capacitors, inductors, and operational amplifiers. Prerequisites: Concurrent registration with or prior completion of PHYS 212 and a processed Engineering (Electrical, Computer, Civil, Mechanical) or Physics major or minor declaration. NOTE: Students who receive credit for ENGR 350 may not receive credit for ENGR 240.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20004

In Person | Lab

St Paul: Schoenecker Center 309

  Steve Albers

Introduction to analog electrical circuits in the time and frequency domains. Circuit analysis techniques including nodal analysis and equivalence theorems will be covered and used to assess a variety of circuits in the time and frequency domains. Students will develop analysis and laboratory skills to analyze and test the operation of circuits composed of resistors, capacitors, inductors, and operational amplifiers. Prerequisites: Concurrent registration with or prior completion of PHYS 212 and a processed Engineering (Electrical, Computer, Civil, Mechanical) or Physics major or minor declaration. NOTE: Students who receive credit for ENGR 350 may not receive credit for ENGR 240.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20103

In Person | Lab

St Paul: Schoenecker Center 309

  Steve Albers

Introduction to analog electrical circuits in the time and frequency domains. Circuit analysis techniques including nodal analysis and equivalence theorems will be covered and used to assess a variety of circuits in the time and frequency domains. Students will develop analysis and laboratory skills to analyze and test the operation of circuits composed of resistors, capacitors, inductors, and operational amplifiers. Prerequisites: Concurrent registration with or prior completion of PHYS 212 and a processed Engineering (Electrical, Computer, Civil, Mechanical) or Physics major or minor declaration. NOTE: Students who receive credit for ENGR 350 may not receive credit for ENGR 240.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20287

In Person | Lab

St Paul: In Person

Instructor: TBD

A hands-on lab providing instruction in fabrication skills used throughout the mechanical engineering curriculum. Training on safety and usage of manual mills, manual lathes, and a wide variety of woodshop equipment.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20288

In Person | Lab

St Paul: In Person

Instructor: TBD

A hands-on lab providing instruction in fabrication skills used throughout the mechanical engineering curriculum. Training on safety and usage of manual mills, manual lathes, and a wide variety of woodshop equipment.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20289

In Person | Lab

St Paul: In Person

Instructor: TBD

A hands-on lab providing instruction in fabrication skills used throughout the mechanical engineering curriculum. Training on safety and usage of manual mills, manual lathes, and a wide variety of woodshop equipment.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20290

In Person | Lab

St Paul: In Person

Instructor: TBD

A hands-on lab providing instruction in fabrication skills used throughout the mechanical engineering curriculum. Training on safety and usage of manual mills, manual lathes, and a wide variety of woodshop equipment.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20263

Online: Asynchronous | Directed Study

Online

Instructor: TBD

This zero credit course is for co-curricular engineering practical training for undergraduate students in the School of Engineering.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20035

In Person | Lecture

St Paul: In Person

Instructor: TBD

Focus is on advanced mechanics topics, failure theories (static and dynamic), and on an understanding of basic machine components. This course will develop the student's creative skills in conceptualizing machines to meet performance criteria by means of a design project. Machine designs will require the understanding and use of machine components such as springs, screws, bearings, basic 4-bar linkages, cams, and gears. Finally, a number of mini labs/workshops on topics that support the design project such as dynamic analysis software, machine component design, and design for manufacture are given. Prerequisite: A minimum grade of C- in (ENGR 170 or ENGR 171), ENGR 220 and ENGR 221, and satisfactory completion of ENGR 255 (or concurrent registration)

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20075

In Person | Lecture

St Paul: In Person

Instructor: TBD

Focus is on advanced mechanics topics, failure theories (static and dynamic), and on an understanding of basic machine components. This course will develop the student's creative skills in conceptualizing machines to meet performance criteria by means of a design project. Machine designs will require the understanding and use of machine components such as springs, screws, bearings, basic 4-bar linkages, cams, and gears. Finally, a number of mini labs/workshops on topics that support the design project such as dynamic analysis software, machine component design, and design for manufacture are given. Prerequisite: A minimum grade of C- in (ENGR 170 or ENGR 171), ENGR 220 and ENGR 221, and satisfactory completion of ENGR 255 (or concurrent registration)

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20040

In Person | Lab

St Paul: In Person

Instructor: TBD

Focus is on advanced mechanics topics, failure theories (static and dynamic), and on an understanding of basic machine components. This course will develop the student's creative skills in conceptualizing machines to meet performance criteria by means of a design project. Machine designs will require the understanding and use of machine components such as springs, screws, bearings, basic 4-bar linkages, cams, and gears. Finally, a number of mini labs/workshops on topics that support the design project such as dynamic analysis software, machine component design, and design for manufacture are given. Prerequisite: A minimum grade of C- in (ENGR 170 or ENGR 171), ENGR 220 and ENGR 221, and satisfactory completion of ENGR 255 (or concurrent registration)

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20077

In Person | Lab

St Paul: In Person

Instructor: TBD

Focus is on advanced mechanics topics, failure theories (static and dynamic), and on an understanding of basic machine components. This course will develop the student's creative skills in conceptualizing machines to meet performance criteria by means of a design project. Machine designs will require the understanding and use of machine components such as springs, screws, bearings, basic 4-bar linkages, cams, and gears. Finally, a number of mini labs/workshops on topics that support the design project such as dynamic analysis software, machine component design, and design for manufacture are given. Prerequisite: A minimum grade of C- in (ENGR 170 or ENGR 171), ENGR 220 and ENGR 221, and satisfactory completion of ENGR 255 (or concurrent registration)

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20184

In Person | Lab

St Paul: In Person

Instructor: TBD

Focus is on advanced mechanics topics, failure theories (static and dynamic), and on an understanding of basic machine components. This course will develop the student's creative skills in conceptualizing machines to meet performance criteria by means of a design project. Machine designs will require the understanding and use of machine components such as springs, screws, bearings, basic 4-bar linkages, cams, and gears. Finally, a number of mini labs/workshops on topics that support the design project such as dynamic analysis software, machine component design, and design for manufacture are given. Prerequisite: A minimum grade of C- in (ENGR 170 or ENGR 171), ENGR 220 and ENGR 221, and satisfactory completion of ENGR 255 (or concurrent registration)

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20078

In Person | Lecture

St Paul: In Person

Instructor: TBD

Principles of dynamics including such topics as kinematics of particles, Newton's Second Law, energy and momentum methods, plane motion of rigid bodies, and forces and acceleration. Applied mathematics is used to solve resulting ordinary differential equations numerically with MATLAB. Emphasis on applications with integrated labs/projects. Prerequisites: Minimum of C- in CISC 130, ENGR 220, MATH 200, and MATH 210

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20079

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of dynamics including such topics as kinematics of particles, Newton's Second Law, energy and momentum methods, plane motion of rigid bodies, and forces and acceleration. Applied mathematics is used to solve resulting ordinary differential equations numerically with MATLAB. Emphasis on applications with integrated labs/projects. Prerequisites: Minimum of C- in CISC 130, ENGR 220, MATH 200, and MATH 210

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20080

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of dynamics including such topics as kinematics of particles, Newton's Second Law, energy and momentum methods, plane motion of rigid bodies, and forces and acceleration. Applied mathematics is used to solve resulting ordinary differential equations numerically with MATLAB. Emphasis on applications with integrated labs/projects. Prerequisites: Minimum of C- in CISC 130, ENGR 220, MATH 200, and MATH 210

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20081

In Person | Lab

St Paul: In Person

Instructor: TBD

Principles of dynamics including such topics as kinematics of particles, Newton's Second Law, energy and momentum methods, plane motion of rigid bodies, and forces and acceleration. Applied mathematics is used to solve resulting ordinary differential equations numerically with MATLAB. Emphasis on applications with integrated labs/projects. Prerequisites: Minimum of C- in CISC 130, ENGR 220, MATH 200, and MATH 210

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20005

In Person | Lecture

St Paul: In Person

Instructor: TBD

Topics include memory mapped I/O, timer applications (input capture, PWM), analog-to-digital, digital-to-analog conversion, interrupts, communication and bus protocols, clocking, low-power design and interface with sensors, actuators and other common microcontroller peripherals. This course has a major design project. Prerequisite: A minimum grade of C- in both ENGR 230 and (CISC 130 or 131). 

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20006

In Person | Lab

St Paul: In Person

Instructor: TBD

Topics include memory mapped I/O, timer applications (input capture, PWM), analog-to-digital, digital-to-analog conversion, interrupts, communication and bus protocols, clocking, low-power design and interface with sensors, actuators and other common microcontroller peripherals. This course has a major design project. Prerequisite: A minimum grade of C- in both ENGR 230 and (CISC 130 or 131). 

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20016

In Person | Lab

St Paul: In Person

Instructor: TBD

Topics include memory mapped I/O, timer applications (input capture, PWM), analog-to-digital, digital-to-analog conversion, interrupts, communication and bus protocols, clocking, low-power design and interface with sensors, actuators and other common microcontroller peripherals. This course has a major design project. Prerequisite: A minimum grade of C- in both ENGR 230 and (CISC 130 or 131). 

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20007

In Person | Lecture

St Paul: Schoenecker Center 314

  Lucas Koerner

A continuation of PHYS 341. An introduction to the practical consequences of Maxwell's equations including propagation, reflection and absorption of electromagnetic waves. Applications include antennas, waveguides, transmission lines, and shielding from electromagnetic interference. Prerequisite: A minimum grade of C- in PHYS 341

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20272

In Person | Lecture

St Paul: O'Shaughnessy Science Hall 327

  Bob Mahmoodi

Analysis of electronic devices and circuits. Topics include Op Amps, Op Amp feedback, and OA applications, linear and non-linear transistor circuit models, single transistor amplifiers, and circuit design techniques. Applications include power electronics, amplifiers, active filters, and integrated frequency analysis/design. Prerequisites: A minimum grade of C- in ENGR 240 or 350

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20278

In Person | Lab

St Paul: Schoenecker Center 308

  Bob Mahmoodi

Analysis of electronic devices and circuits. Topics include Op Amps, Op Amp feedback, and OA applications, linear and non-linear transistor circuit models, single transistor amplifiers, and circuit design techniques. Applications include power electronics, amplifiers, active filters, and integrated frequency analysis/design. Prerequisites: A minimum grade of C- in ENGR 240 or 350

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20024

In Person | Lecture

St Paul: In Person

Instructor: TBD

Continuation of ENGR 345. Topics include network theorems applicable to feedback analysis, amplifier feedback analysis, amplifier frequency analysis, and select circuit topologies commonly found in op amps. Special topics covered include an introduction to switch mode power supplies and an introduction to electrical noise and noise sources. Prerequisite: A minimum grade of C- in ENGR 345

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20049

In Person | Lecture

St Paul: O'Shaughnessy Science Hall 333

  Chong Xu

This course provides scientists and engineers with a background in electrical circuits, electronics and electric machines. Topics include DC, AC and transient circuit analysis, AC 3-phase and power, frequency response and filters, operational amplifiers and active filter, and electric machines; magnetism, magnetic materials, magnetic circuits, DC and AC motors and generators. The course consists of lectures, demonstrations, discussions and an associated hands-on laboratory. Prerequisite: A minimum grade of C- in PHYS 112 or 212

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20082

In Person | Lecture

St Paul: Schoenecker Center 314

  Mohamed Moustafa

This course provides scientists and engineers with a background in electrical circuits, electronics and electric machines. Topics include DC, AC and transient circuit analysis, AC 3-phase and power, frequency response and filters, operational amplifiers and active filter, and electric machines; magnetism, magnetic materials, magnetic circuits, DC and AC motors and generators. The course consists of lectures, demonstrations, discussions and an associated hands-on laboratory. Prerequisite: A minimum grade of C- in PHYS 112 or 212

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20037

In Person | Lab

St Paul: Schoenecker Center 309

Instructor: TBD

This course provides scientists and engineers with a background in electrical circuits, electronics and electric machines. Topics include DC, AC and transient circuit analysis, AC 3-phase and power, frequency response and filters, operational amplifiers and active filter, and electric machines; magnetism, magnetic materials, magnetic circuits, DC and AC motors and generators. The course consists of lectures, demonstrations, discussions and an associated hands-on laboratory. Prerequisite: A minimum grade of C- in PHYS 112 or 212

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20038

In Person | Lab

St Paul: In Person

  Steve Albers

This course provides scientists and engineers with a background in electrical circuits, electronics and electric machines. Topics include DC, AC and transient circuit analysis, AC 3-phase and power, frequency response and filters, operational amplifiers and active filter, and electric machines; magnetism, magnetic materials, magnetic circuits, DC and AC motors and generators. The course consists of lectures, demonstrations, discussions and an associated hands-on laboratory. Prerequisite: A minimum grade of C- in PHYS 112 or 212

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20083

In Person | Lab

St Paul: Schoenecker Center 309

Instructor: TBD

This course provides scientists and engineers with a background in electrical circuits, electronics and electric machines. Topics include DC, AC and transient circuit analysis, AC 3-phase and power, frequency response and filters, operational amplifiers and active filter, and electric machines; magnetism, magnetic materials, magnetic circuits, DC and AC motors and generators. The course consists of lectures, demonstrations, discussions and an associated hands-on laboratory. Prerequisite: A minimum grade of C- in PHYS 112 or 212

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20022

In Person | Lecture

St Paul: In Person

Instructor: TBD

An introduction to materials and their properties. This course introduces students to the fundamentals of materials theory, properties and applications. Topics include properties and applications of metals, polymers, ceramics and composite materials. The course emphasizes characteristics of materials in manufacturing operations and service, including open-ended design issues. Offered in fall semester. Prerequisites: A minimum grade of C- in CHEM 109 (preferred), or CHEM 111 or CHEM 115

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20119

In Person | Lecture

St Paul: In Person

Instructor: TBD

An introduction to materials and their properties. This course introduces students to the fundamentals of materials theory, properties and applications. Topics include properties and applications of metals, polymers, ceramics and composite materials. The course emphasizes characteristics of materials in manufacturing operations and service, including open-ended design issues. Offered in fall semester. Prerequisites: A minimum grade of C- in CHEM 109 (preferred), or CHEM 111 or CHEM 115

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20023

In Person | Lab

St Paul: In Person

Instructor: TBD

An introduction to materials and their properties. This course introduces students to the fundamentals of materials theory, properties and applications. Topics include properties and applications of metals, polymers, ceramics and composite materials. The course emphasizes characteristics of materials in manufacturing operations and service, including open-ended design issues. Offered in fall semester. Prerequisites: A minimum grade of C- in CHEM 109 (preferred), or CHEM 111 or CHEM 115

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20045

In Person | Lab

St Paul: In Person

Instructor: TBD

An introduction to materials and their properties. This course introduces students to the fundamentals of materials theory, properties and applications. Topics include properties and applications of metals, polymers, ceramics and composite materials. The course emphasizes characteristics of materials in manufacturing operations and service, including open-ended design issues. Offered in fall semester. Prerequisites: A minimum grade of C- in CHEM 109 (preferred), or CHEM 111 or CHEM 115

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20120

In Person | Lab

St Paul: In Person

Instructor: TBD

An introduction to materials and their properties. This course introduces students to the fundamentals of materials theory, properties and applications. Topics include properties and applications of metals, polymers, ceramics and composite materials. The course emphasizes characteristics of materials in manufacturing operations and service, including open-ended design issues. Offered in fall semester. Prerequisites: A minimum grade of C- in CHEM 109 (preferred), or CHEM 111 or CHEM 115

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20176

In Person | Lab

St Paul: In Person

Instructor: TBD

An introduction to materials and their properties. This course introduces students to the fundamentals of materials theory, properties and applications. Topics include properties and applications of metals, polymers, ceramics and composite materials. The course emphasizes characteristics of materials in manufacturing operations and service, including open-ended design issues. Offered in fall semester. Prerequisites: A minimum grade of C- in CHEM 109 (preferred), or CHEM 111 or CHEM 115

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20151

In Person | Lecture

St Paul: In Person

Instructor: TBD

Introduction to construction materials commonly used in civil engineering projects, including aggregates, asphalt, concrete, fiber reinforced polymers, masonry, metals, and wood. For each material, topics will include material properties, specifications, laboratory procedures, and test equipment, with an emphasis on ASTM standards. Introduction to asphalt and concrete mix design. Prerequisites: A grade of C- or better in ENGR 221, DASC120, and either CHEM 109 or CHEM 111.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20153

In Person | Lab

St Paul: Schoenecker Center 101

  Rita Lederle

Introduction to construction materials commonly used in civil engineering projects, including aggregates, asphalt, concrete, fiber reinforced polymers, masonry, metals, and wood. For each material, topics will include material properties, specifications, laboratory procedures, and test equipment, with an emphasis on ASTM standards. Introduction to asphalt and concrete mix design. Prerequisites: A grade of C- or better in ENGR 221, DASC120, and either CHEM 109 or CHEM 111.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20669

In Person | Lecture

St Paul: In Person

  Travis Welt

Identification of loads and load paths through a structure. Analysis of internal loading, stress and deflection in trusses, beams and frames. Topics include shear and moment diagrams, influence lines, and determination of deflection through energy methods. Prerequisite: ENGR 221 and MATH 210 with C- or better.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20530

In Person | Lecture

St Paul: In Person

  Mingu Kang

Principles of soil mechanics and geotechnical engineering. Physical and mechanical properties of soils including, shear strength of soil, slope stability, soil stabilization, compaction, consolidation and stress analysis. Role of water in soils including permeability, drainage, and Atterberg limits. Theories related to and design of retaining structures. Design of retaining walls, footings, mat foundations and pile foundations. Engineering design will adhere to professional practice, current codes/standards, considerations for economics and safety. Prerequisites: A grade of C- or better in ENGR 221.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20531

In Person | Lab

St Paul: O'Shaughnessy Science Hall LL13

  Mingu Kang

Principles of soil mechanics and geotechnical engineering. Physical and mechanical properties of soils including, shear strength of soil, slope stability, soil stabilization, compaction, consolidation and stress analysis. Role of water in soils including permeability, drainage, and Atterberg limits. Theories related to and design of retaining structures. Design of retaining walls, footings, mat foundations and pile foundations. Engineering design will adhere to professional practice, current codes/standards, considerations for economics and safety. Prerequisites: A grade of C- or better in ENGR 221.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 22181

In Person | Lab

St Paul: In Person

  Travis Welt

Principles of soil mechanics and geotechnical engineering. Physical and mechanical properties of soils including, shear strength of soil, slope stability, soil stabilization, compaction, consolidation and stress analysis. Role of water in soils including permeability, drainage, and Atterberg limits. Theories related to and design of retaining structures. Design of retaining walls, footings, mat foundations and pile foundations. Engineering design will adhere to professional practice, current codes/standards, considerations for economics and safety. Prerequisites: A grade of C- or better in ENGR 221.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20188

In Person | Lecture

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of civil engineering applications. Topics covered include hydrostatics and pressure variations in non-moving fluids, buoyancy, forces on submerged surfaces, conservation laws of flowing fluids (mass, momentum, and energy), Bernoulli equation, dimensional analysis, viscous internal flow and external flows (drag). The course also introduces pump/fan curves and their incorporation with systems curves in the design of pipe systems. Hands-on engagement of lecture topics, practical hands-on skills, experimental design/build/test projects and utilization of measurement equipment is integrated into course laboratory. Prerequisites: Grade of C- or better in MATH 210 and CHEM 109 or CHEM 111.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20189

In Person | Lab

St Paul: Schoenecker Center LL01

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of civil engineering applications. Topics covered include hydrostatics and pressure variations in non-moving fluids, buoyancy, forces on submerged surfaces, conservation laws of flowing fluids (mass, momentum, and energy), Bernoulli equation, dimensional analysis, viscous internal flow and external flows (drag). The course also introduces pump/fan curves and their incorporation with systems curves in the design of pipe systems. Hands-on engagement of lecture topics, practical hands-on skills, experimental design/build/test projects and utilization of measurement equipment is integrated into course laboratory. Prerequisites: Grade of C- or better in MATH 210 and CHEM 109 or CHEM 111.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20008

In Person | Lecture

St Paul: In Person

Instructor: TBD

This course covers such basic principles as metal forming, metal cutting, plastic molding, and continuous processes. Students will learn statistical evaluation tools such as the meaning of population distributions, means, medians, regression analysis, and standard deviations. Statistical process control and acceptance testing in the context of modern manufacturing processes will be covered. Prerequisite: A minimum grade of C- in MATH 114 and ENGR 221 (or concurrent registration)

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20121

In Person | Lecture

St Paul: In Person

Instructor: TBD

This course covers such basic principles as metal forming, metal cutting, plastic molding, and continuous processes. Students will learn statistical evaluation tools such as the meaning of population distributions, means, medians, regression analysis, and standard deviations. Statistical process control and acceptance testing in the context of modern manufacturing processes will be covered. Prerequisite: A minimum grade of C- in MATH 114 and ENGR 221 (or concurrent registration)

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20017

In Person | Lecture

St Paul: In Person

Instructor: TBD

A study of thermal and mechanical energy and their applications to technology. First law of thermodynamics (energy conservation); second law of thermodynamics (restrictions on energy transformations). Major topics include the analysis of closed and open (steady state and transient) systems, power cycles, thermophysical properties of substances humidity, dew point and other characteristics of non-reacting mixtures. Prerequisites: A minimum grade of C- in CHEM 115 or 109

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20018

In Person | Lab

St Paul: In Person

Instructor: TBD

A study of thermal and mechanical energy and their applications to technology. First law of thermodynamics (energy conservation); second law of thermodynamics (restrictions on energy transformations). Major topics include the analysis of closed and open (steady state and transient) systems, power cycles, thermophysical properties of substances humidity, dew point and other characteristics of non-reacting mixtures. Prerequisites: A minimum grade of C- in CHEM 115 or 109

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20019

In Person | Lab

St Paul: In Person

Instructor: TBD

A study of thermal and mechanical energy and their applications to technology. First law of thermodynamics (energy conservation); second law of thermodynamics (restrictions on energy transformations). Major topics include the analysis of closed and open (steady state and transient) systems, power cycles, thermophysical properties of substances humidity, dew point and other characteristics of non-reacting mixtures. Prerequisites: A minimum grade of C- in CHEM 115 or 109

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20046

In Person | Lecture

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of engineering applications.  Topics covered include fluid properties, hydrostatics and pressure variations in non‐moving fluids,  buoyancy, conservation laws of flowing fluids (mass, momentum, and energy), dimensional  analysis, boundary layers, internal flow, external flow, drag and lift. Experimental uncertainty  analysis is integrated into the course lecture and lab. Also, the evaluation of turbomachinery and  use of pump/blower curves is addressed. Prerequisite: Grade of C- or higher in ENGR 381 and  MATH 200.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20105

In Person | Lecture

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of engineering applications.  Topics covered include fluid properties, hydrostatics and pressure variations in non‐moving fluids,  buoyancy, conservation laws of flowing fluids (mass, momentum, and energy), dimensional  analysis, boundary layers, internal flow, external flow, drag and lift. Experimental uncertainty  analysis is integrated into the course lecture and lab. Also, the evaluation of turbomachinery and  use of pump/blower curves is addressed. Prerequisite: Grade of C- or higher in ENGR 381 and  MATH 200.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20047

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of engineering applications.  Topics covered include fluid properties, hydrostatics and pressure variations in non‐moving fluids,  buoyancy, conservation laws of flowing fluids (mass, momentum, and energy), dimensional  analysis, boundary layers, internal flow, external flow, drag and lift. Experimental uncertainty  analysis is integrated into the course lecture and lab. Also, the evaluation of turbomachinery and  use of pump/blower curves is addressed. Prerequisite: Grade of C- or higher in ENGR 381 and  MATH 200.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20050

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of engineering applications.  Topics covered include fluid properties, hydrostatics and pressure variations in non‐moving fluids,  buoyancy, conservation laws of flowing fluids (mass, momentum, and energy), dimensional  analysis, boundary layers, internal flow, external flow, drag and lift. Experimental uncertainty  analysis is integrated into the course lecture and lab. Also, the evaluation of turbomachinery and  use of pump/blower curves is addressed. Prerequisite: Grade of C- or higher in ENGR 381 and  MATH 200.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20085

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of engineering applications.  Topics covered include fluid properties, hydrostatics and pressure variations in non‐moving fluids,  buoyancy, conservation laws of flowing fluids (mass, momentum, and energy), dimensional  analysis, boundary layers, internal flow, external flow, drag and lift. Experimental uncertainty  analysis is integrated into the course lecture and lab. Also, the evaluation of turbomachinery and  use of pump/blower curves is addressed. Prerequisite: Grade of C- or higher in ENGR 381 and  MATH 200.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20122

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of fluid mechanics in the context of engineering applications.  Topics covered include fluid properties, hydrostatics and pressure variations in non‐moving fluids,  buoyancy, conservation laws of flowing fluids (mass, momentum, and energy), dimensional  analysis, boundary layers, internal flow, external flow, drag and lift. Experimental uncertainty  analysis is integrated into the course lecture and lab. Also, the evaluation of turbomachinery and  use of pump/blower curves is addressed. Prerequisite: Grade of C- or higher in ENGR 381 and  MATH 200.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20203

In Person | Lecture

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of heat transfer in the context of engineering applications. The major topics to be covered include conduction, convection, and radiation. Students will solve steady and unsteady conduction heat transfer problems in both one-dimensional and multi-dimensional coordinate systems. Internal and external convection will be covered as well as heat exchangers and natural convection. Prerequisite: Grades of C- or higher in ENGR 381, ENGR 383 and MATH 210.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20217

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of heat transfer in the context of engineering applications. The major topics to be covered include conduction, convection, and radiation. Students will solve steady and unsteady conduction heat transfer problems in both one-dimensional and multi-dimensional coordinate systems. Internal and external convection will be covered as well as heat exchangers and natural convection. Prerequisite: Grades of C- or higher in ENGR 381, ENGR 383 and MATH 210.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20218

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of heat transfer in the context of engineering applications. The major topics to be covered include conduction, convection, and radiation. Students will solve steady and unsteady conduction heat transfer problems in both one-dimensional and multi-dimensional coordinate systems. Internal and external convection will be covered as well as heat exchangers and natural convection. Prerequisite: Grades of C- or higher in ENGR 381, ENGR 383 and MATH 210.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20219

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of heat transfer in the context of engineering applications. The major topics to be covered include conduction, convection, and radiation. Students will solve steady and unsteady conduction heat transfer problems in both one-dimensional and multi-dimensional coordinate systems. Internal and external convection will be covered as well as heat exchangers and natural convection. Prerequisite: Grades of C- or higher in ENGR 381, ENGR 383 and MATH 210.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20220

In Person | Lab

St Paul: In Person

Instructor: TBD

Introduction to the fundamentals of heat transfer in the context of engineering applications. The major topics to be covered include conduction, convection, and radiation. Students will solve steady and unsteady conduction heat transfer problems in both one-dimensional and multi-dimensional coordinate systems. Internal and external convection will be covered as well as heat exchangers and natural convection. Prerequisite: Grades of C- or higher in ENGR 381, ENGR 383 and MATH 210.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20009

In Person | Lecture

St Paul: O'Shaughnessy Science Hall 328

  Thomas Secord

An introduction to automation and single-input-single-output (SISO) control systems. Emphasis is placed on continuous-time control loop theory and the use of Laplace transforms to design and analyze control systems. Topics include system modeling, block diagram representation, stability, error analysis, and proportional-integral-derivative (PID) controller synthesis. Prerequisites:  A minimum grade of C- in ENGR 240 or 350, MATH 210, CISC 130 or 131.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20010

In Person | Lecture

St Paul: O'Shaughnessy Science Hall 328

  Chong Xu

An introduction to automation and single-input-single-output (SISO) control systems. Emphasis is placed on continuous-time control loop theory and the use of Laplace transforms to design and analyze control systems. Topics include system modeling, block diagram representation, stability, error analysis, and proportional-integral-derivative (PID) controller synthesis. Prerequisites:  A minimum grade of C- in ENGR 240 or 350, MATH 210, CISC 130 or 131.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20012

In Person | Lab

St Paul: Schoenecker Center 310

Instructor: TBD

An introduction to automation and single-input-single-output (SISO) control systems. Emphasis is placed on continuous-time control loop theory and the use of Laplace transforms to design and analyze control systems. Topics include system modeling, block diagram representation, stability, error analysis, and proportional-integral-derivative (PID) controller synthesis. Prerequisites:  A minimum grade of C- in ENGR 240 or 350, MATH 210, CISC 130 or 131.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20013

In Person | Lab

St Paul: Schoenecker Center 310

Instructor: TBD

An introduction to automation and single-input-single-output (SISO) control systems. Emphasis is placed on continuous-time control loop theory and the use of Laplace transforms to design and analyze control systems. Topics include system modeling, block diagram representation, stability, error analysis, and proportional-integral-derivative (PID) controller synthesis. Prerequisites:  A minimum grade of C- in ENGR 240 or 350, MATH 210, CISC 130 or 131.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20021

In Person | Lab

St Paul: Schoenecker Center 310

Instructor: TBD

An introduction to automation and single-input-single-output (SISO) control systems. Emphasis is placed on continuous-time control loop theory and the use of Laplace transforms to design and analyze control systems. Topics include system modeling, block diagram representation, stability, error analysis, and proportional-integral-derivative (PID) controller synthesis. Prerequisites:  A minimum grade of C- in ENGR 240 or 350, MATH 210, CISC 130 or 131.

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20187

In Person | Lecture

St Paul: In Person

Instructor: TBD

An overview of the latest trends in the Embedded Computing Systems area. Course topic changes from year to year. The course deals with both the technical as well as societal aspects of the trend. Prerequisites: ENGR 331 with a grade of C- or better OR permission of instructor.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20528

In Person | Lecture

St Paul: In Person

  Rita Lederle

Introduction to the design of steel structures; behavior of tension, compression, bending and combined force members and their connections; theoretical, experimental, and practical bases for proportioning members and their connections. Study of the strength, behavior, and design of reinforced concrete members subjected to axial forces, shear forces and moment forces. Prerequisite: A grade of C- or better in ENGR 363 and ENGR 364

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20529

In Person | Lab

St Paul: In Person

  Rita Lederle

Introduction to the design of steel structures; behavior of tension, compression, bending and combined force members and their connections; theoretical, experimental, and practical bases for proportioning members and their connections. Study of the strength, behavior, and design of reinforced concrete members subjected to axial forces, shear forces and moment forces. Prerequisite: A grade of C- or better in ENGR 363 and ENGR 364

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20245

In Person | Lecture

St Paul: In Person

  Mingu Kang

Introduction to design of transportation systems. Principles of geometric roadway design, traffic modeling and forecasting, traffic signal operation and timing. Land use, social issues, and planning for multi- modal transportation systems. Alternative transportation modes including bike, pedestrian, and mass transit. Basics of pavement design. Prerequisite: DASC 120, ENGR 160, ENGR 221 and ENGR 222 with a C- or better

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20382

In Person | Lecture

St Paul: In Person

  Ali Ling

Introduction to water resources engineering including analysis and design of hydraulic systems and hydrological assessment. Hydrological cycle, analysis and urban hydrology. Design elements of pipe and channel flow including groundwater flow, distribution systems, pumping systems, reservoirs and storm sewer collection systems. Prerequisites: ENGR 368 with C- or better.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 22184

In Person | Lecture

St Paul: In Person

  Jose Capa Salinas

Advanced topics in the design of steel structures; behavior of members subject to combined forces, composite members, built up members, advanced connection design, and stability. Theoretical, experimental, and practical bases for proportioning members and their connections. Prerequisite: A minimum grade of C- in ENGR 464 or ENGR 365.

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20532

In Person | Lecture

St Paul: In Person

  Ali Ling

This course is designed to introduce students to process design and water treatment, including concepts, simple models, and sizing/design. Topics will also include sustainable water sourcing and  design of pumps and pipes.  The course will be split between learning about water treatment processes and working on case studies relevant to local treatment plants. Prerequisite:  CHEM 111 or CHEM 109.

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20533

In Person | Lecture

St Paul: In Person

  Ali Ling

This course is designed to introduce students to wastewater treatment, including biological (secondary) wastewater treatment and industrial wastewater treatment topics. The course will be about split between learning about wastewater treatment processes and working on case studies relevant to local facilities. A course project will involve building a process model of a wastewater treatment plant and using it to design and troubleshoot the system. Prerequisite:  ENGR 468 with grade of C- or higher

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20014

In Person | Lecture

St Paul: In Person

Instructor: TBD

A continuation of ENGR 480 involving the application of engineering principles to the solution of real problems in an actual industrial setting. Student design teams will work under the direction of faculty advisers and industry liaisons. Opportunity will be provided for objective formulation, analysis, synthesis and evaluation of alternative solutions. Prerequisite: ENGR 480

4 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20181

In Person | Lab

St Paul: In Person

Instructor: TBD

A continuation of ENGR 480 involving the application of engineering principles to the solution of real problems in an actual industrial setting. Student design teams will work under the direction of faculty advisers and industry liaisons. Opportunity will be provided for objective formulation, analysis, synthesis and evaluation of alternative solutions. Prerequisite: ENGR 480

0 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20177

In Person | Topics Lecture 1

St Paul: In Person

Instructor: TBD

The subject matter of these courses will vary from year to year, but will not duplicate existing courses. Descriptions of these courses are available in Classfinder, View Searchable Class Schedule

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20314

In Person | Topics Lecture 2

St Paul: In Person

Instructor: TBD

The subject matter of these courses will vary from year to year, but will not duplicate existing courses. Descriptions of these courses are available in Classfinder, View Searchable Class Schedule

2 Credits

Subject: Engineering (UG) (ENGR)

CRN: 20679

In Person | Topics Lecture 4

St Paul: In Person

Instructor: TBD

The subject matter of these courses will vary from year to year, but will not duplicate existing courses. Descriptions of these courses are available in Classfinder, View Searchable Class Schedule

2 Credits