SE 1. Introduction to Structures and Design: Introduction to fundamentals of structures and how structures work. Overview of structural behavior and structural design process through hands-on projects. Lessons learned from structural failures. Professional ethics. Role and responsibility of structural engineers. Introduction to four structural engineering focus sequences. Prerequisites: SE major.
SE 2. Structural Materials: Properties and structures of engineering materials, including metals and alloys, ceramics, cements and concretes, polymers, and composites. Elastic deformation, plastic deformation, fracture, fatigue, wearing, and corrosion. Selection of engineering materials based on performance and cost requirements. Prerequisites: grades of C- or better Chem. 6A, and Phys. 2A. (See SE 104 for newer version)
SE 2L. Structural Materials Lab: Materials testing and/or processing for metals and alloys, polymers and composites, cements, and wood. Materials selection and structural design to meet functional and cost requirements. Structural construction and testing. Use of computer resources. Prerequisites: Chem 6A, Phys 2A, and SE 2. (See SE 104L for newer version)
SE 3. Graphical Communication for Engineering Design: Use of computer graphics (CAD software) to communicate engineering designs. Includes visualization, sketching, 2D and 3D graphics standards, dimensioning, tolerance, assemblies, and prototyping/testing with light manufacturing methods. Project/system management software, i.e., building information modeling (BIM), will be introduced. Prerequisites: SE 1.
SE 7. Spatial Visualization: Spatial visualization is the ability to manipulate 2D and 3D shapes in one's mind. In this course, students will perform exercises that increase their spatial visualization skills. Prerequisites: None.
SE 9. Algorithms and Programming for Structural Engineering: Introduction to the Matlab environment. Variables and types, statements, functions, blocks, loops, and branches. Algorithm development. Functions, function handles, input and output arguments. Data encapsulation and object-oriented programming. Toolboxes and libraries. Models from physics (mechanical and thermodynamics) are used in exercises and projects. Prerequisites: grades of C- or better in Math 20D and Math 18
SE 10A. Design Competition—Design, Build, and Fly Aircraft: (Cross-listed with MAE 92A.) Student teams design, build, and fly unmanned aircraft for a national student competition. Students concentrate on vehicle system design including aerodynamics, structures, propulsion, and performance. Teams engineering, fabricate the aircraft, submit a design report, and prep aircraft for competition. Prerequisites: consent of instructor.
SE 18. Applied Linear Algebra for Engineers: Applied linear algebra for engineering students. Emphasis on matrix algebra as applied to linear equation solving and analysis of eigenvalue problems dealing with the deformation of solid bodies and structures. Concepts of linear spaces, vector algebra, indicial notations, introduction to tensors, and curl and divergence developed as part of the algebraic methodology. Detailed coverage of theory of solid deformation. Matrix factorization by a variety of techniques used to solve linear systems. Prerequisites: MATH10C or MATH20C or MATH31BH
SE 101A. Mechanics I: Statics: Statics of particles and rigid bodies in two and three dimensions using vector representation; free body diagrams; analysis of trusses, frames, and machines; internal forces; shear force and bending moment diagrams; equilibrium problems with friction; introduction to moment of inertia. Prerequisites: grade of C- or better in Math 20C and Phys. 2A.
SE 101B. Mechanics II: Dynamics: Kinematics and kinetics of particles in two- and three-dimensional motion. Newton's equations of motion. Energy and momentum methods. Impulsive motion and impact. Systems of particles. Kinetics and kinematics of rigid bodies in 2-D. Introduction to 3-D dynamics of rigid bodies.. Prerequisites: grades of C- or better in SE 101A (or MAE 130A).
SE 101C. Structural Mechanics III: Vibrations: Free and forced vibrations of damped 1-DOF systems; vibrations isolation, impact and packaging problems. Analysis of discrete MDOF systems using matrix representation; normal mode of frequencies and modal matrix formulation. Lagrange's equations. Modal superposition for analysis of continuous vibrating systems. Prerequisites: grades of C- or better in Math 18 and SE 101B (or MAE 130B).
SE 103. Conceptual Structural Design: Introduction to structural design approaches for civil structures. Structural materials. Loads and load paths. Gravity & lateral load elements and systems. Code design fundamentals. Construction methods. Structural idealization. Hand and computer methods of analysis. Experimental methods applied through team-based projects. Program or materials fee may apply. Prerequisites: SE 9, SE 101A (or MAE 130A), SE 104, and SE 104L.
SE 104. Structural Materials: Properties and structures of engineering materials, including metals and alloys, ceramics, cements and concretes, wood, polymers, and composites. Elastic deformation, plastic deformation, fracture, fatigue, creep. Selection of engineering materials based on performance and cost requirements. Measurement techniques. Prerequisites: SE 1 and SE 101A (or MAE 130A).
SE 104L. Structural Materials Lab: Materials testing for cement and concrete, metals and alloys, polymers and composites, and wood. Materials selection and structural design to meet functional and cost requirements. Structural construction and testing. Materials measurement techniques. Prerequisite: SE 104. (May be taken concurrently with SE 104 with department permission via EASY request.)
SE 110A. Solid Mechanics I: Concepts of stress and strain. Hooke’s law. Stress transformation. Axial loading of bars. Torsion of circular shafts. Torsion of thin-walled members. Pure bending of beams. Unsymmetric bending of beams. Shear stresses in beams. Shear stresses in thin-walled beams. Shear center. Differential equation of the deflection curve. Deflections and slopes of beams from integration methods. Statically determinate and indeterminate problems. Prerequisites: Math 20D and SE 101A (or MAE 130A).
SE 110B. Solid Mechanics II: Advanced concepts in the mechanics of deformable bodies. Unsymmetrical bending of symmetrical and unsymmetrical sections. Bending of curved beams. Shear center and torsional analysis of open and closed sections. Stability analysis of columns, lateral buckling. Application of the theory of elasticity in rectangular coordinates. Prerequisite: grade of C- or better in SE 110A, SE majors.
SE 115. Fluid Mechanics for Structural Engineering: Fluid statics, hydrostatic forces; integral and differential forms of conservation equations for mass, momentum and energy; Bernoulli equation; dimensional analysis; viscous pipe flow; external flow, boundary layers; open channel flow. Prerequisites: Phys 2A and Math 20D.
SE 121A. Introduction to Computing for Engineers: Introduction to engineering computing. Interpolation, integration, differentiation. Ordinary differential equations. Nonlinear algebraic equations. Systems of linear algebraic equations. Representation of data in the computer. Prerequisites: SE 9 and SE 101A (or MAE 130A).
SE 121B. Computing Projects in Structural Engineering: Exploration of numerical algorithms in engineering computations. Centered around computing projects. Matrix eigenvalue problems, boundary value
problems, solution of systems of nonlinear algebraic equations, optimization. Prerequisite: SE 101C (or MAE 130C) and SE 121A.
SE 125. Statistics, Probability and Reliability: Probability theory. Statistics, data analysis and inferential statistics, distributions, confidence intervals. Introduction to structural reliability and random phenomena. Applications to components and systems. Prerequisite: SE major.
SE 130A. Structural Analysis: Classical analysis methods of determinate and indeterminate structures. Deflection calculation of beams and frames, work-energy methods, flexibility method, slope-deflection method, moment distribution method, approximate structural analysis, influence line concept for moving loads. Prerequisite: grade of C- or better in SE 110A.
SE 130B. Structural Analysis: Matrix methods of analysis for structures comprised of a large number of truss and beam-column structural elements. Development of the underlying mathematical formulations based on matrix structural analysis, and implementation of computer codes for the analysis of civil, mechanical, and aerospace structures. Prerequisite: grades of C- or better SE 130A.
SE 131. Finite Element Analysis: Development of finite element models based upon the Galerkin method. Application to static and dynamic heat conduction and stress analysis. Formulation of initial boundary value problem models, development of finite element formulas, solution methods, and error analysis and interpretation of results. Prerequisites: SE 101C (or MAE 130C), SE 121B, and SE 130B (co-requisite).
SE 140A. Professional Issues and Design for Civil Structures I: Part I of multidisciplinary team experience to design, analyze, build, and test civil/geotechnical engineering components and systems considering codes, regulations, alternative design solutions, economics, sustainability, constructability, reliability and aesthetics. Professionalism, technical communication, project management, teamwork, and ethics in engineering practice. Prerequisites: SE 130B and SE 150.
SE 140B. Professional Issues and Design for Civil Structures II: Part II of multidisciplinary team experience to design, analyze, build, and test civil/geotechnical engineering components and systems considering codes,regulations, alternative design solutions, economics, sustainability, constructability, reliability and aesthetics. Professionalism, technical communication, project management, teamwork, and ethics in engineering practice. Prerequisites: SE 140A, SE 151A, and SE 181.
SE 142. Design of Composite Structures: Introduction to advanced composite materials and their applications. Fiber and matrix properties, micromechanics, stiffness, ply-by-ply stress, hygrothermal behavior, and failure prediction. Lab activity will involve design, analysis, fabrication, and testing of composite structure. Prerequisites: SE 110A, SE 110B, and SE 160A.
SE 143A. Aerospace Structural Design I: Conceptual and preliminary structural design of aircraft and space vehicles. Minimum-weight design of primary structures based upon mission requirements and configuration constraints. Multi-criteria decision making. Team projects include layout, material selection, component sizing, fabrication, and cost. Oral presentations. Written reports. Prerequisites: SE 3, SE 142, and SE 160B.
SE 143B. Aerospace Structural Design II: Detailed structural design of aircraft and space vehicles. Composite material design considerations. Multidisciplinary design optimization. Introduction to aerospace computer-aided design and analysis tools. Team projects include the analysis, fabrication, and testing of a flight vehicle component. Oral presentations. Written reports. Prerequisites: SE 143A.
SE 150. Design of Steel Structures: Design concepts and loadings for structural systems. Working stress, ultimate strength design theories. Properties of structural steel. Elastic design of tension members, beams, and columns. Design of bolted and welded concentric and eccentric connections, and composite floors. Introduction to plastic design. Prerequisites: SE 130A.
SE 151A. Design of Reinforced Concrete: Concrete and reinforcement properties. Service and ultimate limit state analysis and design. Design of detailing of structural components.
Prerequisites: SE 103 and SE 130A.
SE 151B. Design of Prestressed Concrete: Mechanical properties of concrete and reinforcing material including creep, shrinkage, and stress relaxation. Concept and application of prestressed concrete. Analysis and design of prestressed concrete structures and components including continuous beams and composite construction. Calculation of deflection and prestress losses
Prerequisite: grade of C- or better in SE 151A.
SE 152. Seismic Design of Structures: Seismic design philosophy. Ductility concepts. Lateral force resisting systems. Mechanisms of nonlinear deformation. Methods of analysis. Detailing of structural steel and reinforced concrete elements. Lessons learned from past earthquakes. Multistory building design project.
Prerequisites: SE 130B, SE 150, and SE 151A.
SE 154. Design of Timber Structures: Properties of wood as a building material. Analysis and design of wood beams and columns. Lateral analysis for wind/seismic loading using the IBC. Distribution of lateral forces through a wood structure. Shear wall and diaphragm design. Wood connections introduction. Prerequisites: grades of C- or better in SE 103 and SE 130A.
SE 160A. Aerospace Structural Mechanics I: Aircraft and spacecraft flight loads and operational envelopes, three-dimensional stress/strain relations, metallic and composite materials, failure theories, three-dimensional space trusses and stiffened shear panels, combined extension-bend-twist behavior of thin-walled multi-cell aircraft and space vehicle structures, modulus-weighted section properties, shear center. Prerequisites: SE 2 (See SE 104), SE 2L (See SE 104L), SE 101B (or MAE 130B), and SE 110A.
SE 160B. Aerospace Structural Mechanics II: Analysis of Aerospace structures via work-energy principles and finite element analysis. Bending of metallic and laminated composite plates and shells. Static vibration, and buckling analysis of simple and built-up aircraft structures. Introduction to wing divergence and flutter. Fastener analysis. Prerequisites: SE 101C (or MAE 130C) and SE 160A.
SE 163. Nondestructive Evaluation and Design: Fourier signal processing, liquid penetrant, elastic wave propagation, ultrasonic testing, impact-echo, acoustic emission testing, infrared thermography. Prerequisites: grades of C- or better in SE 110A and SE 110B; SE major.
SE 164. Sensors and Data Acquisition for Structural Engineering: Theory, design and applications of sensor technologies in the context of structural engineering and structural health monitoring. Topics include: sensors and sensing mechanisms; measurement uncertainty; signal conditioning and interface circuits; data acquisition; analog/digital circuits; and emerging sensors. Prerequisites: SE 101C (or MAE 130C) and SE 110A.
SE 165. Structural Health Monitoring: A modern paradigm of structural health monitoring as it applies to structural and mechanical systems is presented. Concepts in data acquisition, feature extraction, data normalization, and statistical modeling will be introduced in an integrated context. MATLAB-based exercise. Term project. Prerequisites: SE 101C (or MAE 130C).
SE 167. Signal Processing and Spectral Analysis for Structural Engineering: Signal processing is widely used in engineering and physical sciences. This course discusses techniques to analyze signals (or data), particularly related to structural dynamic response focusing on time/frequency domain data analyses (Fourier transform, digital filtering, and feature extraction). Prerequisites: SE 101C (or MAE 130C). **See SE 207 section taught by CH Loh for Winter 2019 quarter.
SE 168. Structural System Testing and Model Correlation: Dynamic/model testing of structures: test planning/execution, actuation, sensing, and data acquisition, signal processing, data conditioning, test troubleshooting. Methods of updating finite element structural models to correlate with dynamic test results. Model/test correlation assessment in industrial practice. Knowledge of MATLAB required. Prerequisites: SE 101C (or MAE 130C) and SE 131.
SE 171. Aerospace Structures Repair: Review methods used to repair aerospace structures. Emphasis on primary load-bearing airframe structures and analysis/design of substantiate repairs. Identification of structural/corrosion distress, fatigue cracking, damage tolerance, integrity and durability of built-up members, patching, health monitoring. Prerequisites: SE 160A.
SE 180. Earthquake Engineering: Seismic hazards. Ground motions. Dynamic analysis of structures under earthquake excitation. Elastic and inelastic response spectra. Modal analysis. Linear/nonlinear time history analysis. Seismic Code. Engineering seismology. Basics of Earthquake resistant design. Prerequisites:grades of C- or better in SE 110A and SE 130A.
SE 181. Geotechnical Engineering: General introduction to the mechanics of soils, including; composition and classification, compaction, compressibility and consolidation, permeability and seepage, stress distribution, settlement and shear strength, as well as soil exploration, sampling, and in-situ testing techniques. Physical laboratory taken concurrently. Prerequisites: grades of C- or better in SE 110A, SE major.
SE 182. Foundation Engineering: Application of soil mechanics to the analysis, design, and construction of
foundations for structures. Soil exploration, sampling, and in-situ testing techniques. Stress distribution and settlement of structures. Bearing capacities of shallow foundations and effects on structural design. Analysis of axial and lateral capacity of deep foundations, including drilled piers and driven piles. Prerequisite: SE 181, SE major.
SE 184. Ground Improvement: Concepts underpinning mechanical, hydraulic, chemical and inclusion-based methods of ground improvement will be discussed. Students will be able to understand the advantages, disadvantages and limitations of the various methods; and develop a conceptual design for the most appropriate improvement strategy. Prerequisite: SE 181.
SE 192. Senior Seminar: The Senior Seminar is designed to allow senior undergraduates to meet with faculty members to explore an intellectual topic in structural engineering. Topics will vary from quarter to quarter. Enrollment is limited to twenty students with preference given to seniors. Prerequisites: SE major. Department stamp and/or consent of instructor.
SE 195. Teaching: Teaching and tutorial assistance in a SE course under supervision of instructor. Not more than four units may be used to satisfy graduation requirements. (P/NP grades only.) Prerequisites: B average in major, upper-division standing and consent of department chair. Department stamp required.
SE 197. Engineering Internship: An enrichment program, available to a limited number of undergraduate students, which provides work experience with industry, government offices, etc., under the supervision of a faculty member and industrial supervisor. Coordination of the Engineering Internship is conducted through UC San Diego’s Academic Internship Program. Prerequisites: completion of ninety units with a 2.5 GPA and consent of department chair. Department stamp required.
SE 198. Directed Study Group: Directed group study, on a topic or in a field not included in the regular department curriculum, by special arrangement with a faculty member. (P/NP grades only.) Prerequisites: consent of instructor or department stamp.
SE 199. Independent Study: Independent reading or research on a problem by special arrangement with a faculty member. (P/NP grades only.) Prerequisites: consent of instructor and departmental approval via EASY request.