This course familiarizes students with key aspects of structure and form in poetry, fiction and creative nonfiction. Students focus in turn on such elements of creative writing as imagery, diction, figurative language, character, setting and plot. Students draft, workshop and revise three pieces of writing over the course of the semester, one each in the genres of poetry, fiction and creative nonfiction. Enrollment limited to 15.

This course familiarizes students with key aspects of structure and form in poetry, fiction and creative nonfiction. Students focus in turn on such elements of creative writing as imagery, diction, figurative language, character, setting and plot. Students draft, workshop and revise three pieces of writing over the course of the semester, one each in the genres of poetry, fiction and creative nonfiction. Enrollment limited to 15.

This course familiarizes students with key aspects of structure and form in poetry, fiction and creative nonfiction. Students focus in turn on such elements of creative writing as imagery, diction, figurative language, character, setting and plot. Students draft, workshop and revise three pieces of writing over the course of the semester, one each in the genres of poetry, fiction and creative nonfiction. Enrollment limited to 15.

Offered as ENG 112 and PYX 112. This course offers the opportunity to read contemporary poetry and meet the poets who write it. The course consists of class meetings alternating with public poetry readings by visiting poets. This course does not count toward the English major. S/U only. Course may be repeated.

The goal of this seminar is to introduce students to several approaches used to model, understand, simulate and forecast engineering processes. One approach covered is the use of artificial neural networks—a branch of artificial intelligence (AI) with connections to the brain. Other approaches covered are based upon probability and statistics and include auto-regressive moving average (ARIMA) processes. Although students learn about the theory behind these approaches, the emphasis of the course is on their application to model processes throughout the field of engineering.

This course introduces students to the fundamentals of mechanics of materials from a static failure analysis framework. Structural behavior is analyzed, along with the material and geometric contributions to this behavior. Lecture topics are complemented with hands-on project work designed to help students make connections between the theoretical and experimental behavior of materials. Prerequisite: EGR 270. Restrictions: Engineering majors only.

This is the second course in a two-semester sequence designed to introduce students to fundamental theoretical principles and analysis of mechanics of continuous media, including solids and fluids. Concepts and topics to be covered in this course include intensive and extensive thermophysical properties of fluids; control-volume and differential expressions for conservation of mass, momentum and energy; dimensional analysis; and an introduction to additional topics such as aerodynamics, open-channel flow and the use of fluid mechanics in the design process. Required concurrent laboratory.

This is the second course in a two-semester sequence designed to introduce students to fundamental theoretical principles and analysis of mechanics of continuous media, including solids and fluids. Concepts and topics to be covered in this course include intensive and extensive thermophysical properties of fluids; control-volume and differential expressions for conservation of mass, momentum and energy; dimensional analysis; and an introduction to additional topics such as aerodynamics, open-channel flow and the use of fluid mechanics in the design process. Required concurrent laboratory.

This is the second course in a two-semester sequence designed to introduce students to fundamental theoretical principles and analysis of mechanics of continuous media, including solids and fluids. Concepts and topics to be covered in this course include intensive and extensive thermophysical properties of fluids; control-volume and differential expressions for conservation of mass, momentum and energy; dimensional analysis; and an introduction to additional topics such as aerodynamics, open-channel flow and the use of fluid mechanics in the design process. Required concurrent laboratory.

Knowledge of the mechanical and material behavior of the skeletal system is important for understanding how the human body functions and how the biomechanical integrity of the tissues comprising the skeletal system are established during development, maintained during adulthood and restored following injury. This course provides a rigorous approach to examining the mechanical behavior of the skeletal tissues, including bone, tendon, ligament and cartilage. Engineering, basic science and clinical perspectives are integrated to study applications in the field of orthopaedic biomechanics.