Fundamentals of Structural Engineering

1. Front Matter

   Pages i-xxvii

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2. Statically Determinate Structures

   1. Front Matter

      Pages 1-1

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   2. Introduction to Structural Engineering

      • Jerome J. Connor, Susan Faraji

      Pages 3-49

   3. Statically Determinate Truss Structures

      • Jerome J. Connor, Susan Faraji

      Pages 51-183

   4. Statically Determinate Beams

      • Jerome J. Connor, Susan Faraji

      Pages 185-353

   5. Statically Determinate Plane Frames

      • Jerome J. Connor, Susan Faraji

      Pages 355-441

   6. Cable Structures

      • Jerome J. Connor, Susan Faraji

      Pages 443-488

   7. Statically Determinate Curved Members

      • Jerome J. Connor, Susan Faraji

      Pages 489-544

   8. Shallow Foundations

      • Jerome J. Connor, Susan Faraji

      Pages 545-597

   9. Vertical Retaining Wall Structures

      • Jerome J. Connor, Susan Faraji

      Pages 599-632

3. Statically Indeterminate Structures

   1. Front Matter

      Pages 633-633

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   2. The Force Method

      • Jerome J. Connor, Susan Faraji

      Pages 635-735

   3. The Displacement Method

      • Jerome J. Connor, Susan Faraji

      Pages 737-842

   4. Approximate Methods for Estimating Forces in Statically Indeterminate Structures

      • Jerome J. Connor, Susan Faraji

      Pages 843-884

   5. Finite Element Displacement Method for Framed Structures

      • Jerome J. Connor, Susan Faraji

      Pages 885-951

4. Practice of Structural Engineering

   1. Front Matter

      Pages 953-953

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   2. Multi-span Horizontal Structures

      • Jerome J. Connor, Susan Faraji

      Pages 955-998

   3. Lateral Load Issues for Buildings

      • Jerome J. Connor, Susan Faraji

      Pages 999-1067

   4. Vertical Loads on Multistory Buildings

      • Jerome J. Connor, Susan Faraji

      Pages 1069-1120

5. Back Matter

   Pages 1121-1143

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Fundamentals of Structural Engineering provides a balanced, seamless treatment of both classic, analytic methods and contemporary, computer-based techniques for conceptualizing and designing a structure. The book?s principle goal is to foster an intuitive understanding of structural behavior based on problem solving experience for students of civil engineering and architecture who have been exposed to the basic concepts of engineering mechanics and mechanics of materials.

Distinct from many undergraduate textbooks, which are  focused mainly on either teaching manual analysis methods and applying them to simple, idealized structures or reformulating structural analysis methods in terms of matrix notation, this text instead encourages the student to develop intuition about structural behavior. The authors of this text recognize the notion that engineers reason about behavior using simple models and intuition they acquire through problem solving. The approach adopted inthis text develops this type of intuition by presenting extensive, realistic problems and case studies together with computer simulation, which allows rapid exploration of  how a structure responds to changes in geometry and physical parameters.

• Cable Structures
• Finite Element Displacement Method
• Lateral load issues for buildings
• Multi-span horizontal structures
• Statically Determinate Beams
• Statically Determinate Curved Members
• Statically Determinate Plane Frames
• Structural Engineering
• The Force Method
• Truss Structures

From the reviews:

“The intended audience of this book is that of students majoring in civil engineering and architecture who have obtained preliminary concepts of engineering mechanics and mechanics of materials. The main objective is to develop the student’s ability to analyze structures using manual computational procedures and validate computer-based predictions of structural response. … The book is sufficiently comprehensive and can be used for elementary and higher-level undergraduate subjects.” (Irina Alexandrovna Bolgrabskaya, Zentralblatt MATH, Vol. 1256, 2013)

• Department of Civil & Environmental Engineering, Massachusetts Institute of Technology, Cambridge, USA

  Jerome J. Connor

• Department of Civil & Environmental Engineering, University of Massachusetts-Lowell, Lowell, USA

  Susan Faraji

Dr. Jerome J. Connor is Professor of Civil Engineering at Massachusetts Institute of Technology. His research interests include computational mechanics, structural analysis, motion based structural design, and novel design methodologies for structural systems and has taught courses in computational mechanics and structural engineering. In recent years Connor’s work has involved motion based design and damage assessment of engineering materials and he is directing a number of projects related to the applications of structural control to large civil structures as well as investigating methods to quantify damage in engineering materials.

Dr. Susan Faraji has been Professor of Structural Engineering in the Department of Civil and Environmental Engineering at the University of Massachusetts at Lowell since 1984. Dr. Faraji has close to three decades of teaching, research, publication, and consulting experience and has taught a wide range of courses at the undergraduate and at thegraduate level, such as Concrete Design, Steel Design, Bridge Design, Seismic Design, Concrete Design, Finite Elements, Structural Dynamics, and Behavior of Structures. Her professional work involves the analysis, design (using the latest design codes), and computer modeling of a wide range of structures. She has worked on more than 30 bridges and on aircraft, elevators, pontoons, ramps, concrete parking garages, domes, culverts, retaining walls, and steel and concrete frame buildings.

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