This course introduces the basic theoretical concepts, procedures and methodologies needed to understand the mechanical behavior of objects in static equilibrium. Topics to be covered include 2d and 3d particle and rigid body equilibrium; analysis of frames, trusses, beams and machines; centroids; distributed loading; moment of inertia; internal forces and moments; and an introduction to stress and strain. In addition to developing competence in applying standard problem-solving procedures, students also apply their understanding in real world contexts.

This course introduces the basic theoretical concepts, procedures and methodologies needed to understand the mechanical behavior of objects in static equilibrium. Topics to be covered include 2d and 3d particle and rigid body equilibrium; analysis of frames, trusses, beams and machines; centroids; distributed loading; moment of inertia; internal forces and moments; and an introduction to stress and strain. In addition to developing competence in applying standard problem-solving procedures, students also apply their understanding in real world contexts.

This course introduces the basic theoretical concepts, procedures and methodologies needed to understand the mechanical behavior of objects in static equilibrium. Topics to be covered include 2d and 3d particle and rigid body equilibrium; analysis of frames, trusses, beams and machines; centroids; distributed loading; moment of inertia; internal forces and moments; and an introduction to stress and strain. In addition to developing competence in applying standard problem-solving procedures, students also apply their understanding in real world contexts.

This course introduces the basic theoretical concepts, procedures and methodologies needed to understand the mechanical behavior of objects in static equilibrium. Topics to be covered include 2d and 3d particle and rigid body equilibrium; analysis of frames, trusses, beams and machines; centroids; distributed loading; moment of inertia; internal forces and moments; and an introduction to stress and strain. In addition to developing competence in applying standard problem-solving procedures, students also apply their understanding in real world contexts.

Students in this course investigate and design water resources infrastructure – for hydropower, water supply, wastewater treatment, stormwater management and irrigation. Those technologies are introduced through historical and contemporary examples, along with a theme of the importance of place in engineering design. In contrast to design as invention, this course puts the emphasis on the adaptation of common designs to particular places, as influenced by climate, physical geography, culture, history, economics, politics and legal frameworks.

This course focuses on the global transition of energy systems toward sustainability and net-zero emissions. There is interest across the planet to transition to energy systems that emit zero pollutant emissions – but is this actually possible? Students learn about both the engineering elements of energy systems and the societal and government initiatives for The Energy Transition.