"Structural analysis is a branch of solid mechanics which...determine the effect of loads on the physical structures and their components."
The process of determining the forces and stresses acting on a structure and assessing its strength and stability.
Mechanics of Materials: This topic is concerned with the study of the behavior of materials subjected to various types of loading, such as tension, compression, bending, and torsion.
Statics: Statics is the study of the behavior of structures and the forces acting on them when they are in a state of rest.
Strength of Materials: Strength of Materials is a branch of mechanics that deals with the strength and deformation of materials when they are subjected to external loads.
Structural Loads: This topic is concerned with the estimation and calculation of various types of loads that a structure may be subjected to, such as dead loads, live loads, wind loads, and seismic loads.
Structural Analysis Methods: Structural Analysis Methods refer to the various techniques used for analyzing the behavior of a structure under various loading conditions, such as the method of joints, method of sections, and the finite element method.
Load Path Analysis: Load Path Analysis involves the determination of how loads are transmitted through a structure and how these loads are distributed to various parts of the system.
Structural Design: This topic is concerned with the selection of appropriate structural elements, materials, and systems to withstand the loads that a structure may be subjected to.
Foundation Design: Foundation Design is the process of ensuring that the foundation of a structure is adequate to support the loads that the structure may be subjected to, and that the structure will remain stable and secure throughout its lifespan.
Structural Rehabilitation and Retrofitting: Structural Rehabilitation and Retrofitting refer to the techniques used to reinforce existing structures that may have become weakened or damaged over time.
Building Codes and Standards: Building Codes and Standards specify the minimum requirements that structures must meet to ensure safety, reliability, and durability, and are an essential part of the construction process.
Static analysis: A structural design method that analyzes the forces on a structure due to static loads, such as gravity or wind.
Dynamic analysis: A structural design method that takes into account the response of a structure to dynamic or time-varying loads, such as earthquake or wind-induced vibrations.
Modal analysis: A structural design method that identifies the natural frequencies and modes of vibration of a structure.
Finite element analysis: A structural design method that divides a structure into small elements and analyzes each element separately to determine the overall behavior of the structure.
Buckling analysis: A structural design method that assesses the buckling capacity of a structure under compressive loads.
Fatigue analysis: A structural design method that evaluates the structural integrity of members subjected to repetitive loading over time.
Nonlinear analysis: A structural design method that accounts for the behavior of a structure under extreme conditions, such as large deformations, material yielding, or collapse.
Seismic analysis: A structural design method that models the response of a structure to seismic forces, such as ground motion or earthquakes.
Wind analysis: A structural design method that evaluates the wind loads on a structure and their effect on the structural stability and integrity.
Thermal analysis: A structural design method that considers the impact of temperature variations on the performance of a structure.
"Uses simplified models for solids like bars, beams, and shells."
"The models used in structure analysis are often differential equations in one spatial variable."
"Structures subject to this type of analysis include all that must withstand loads, such as buildings, bridges, aircraft, and ships."
"Structural analysis uses ideas from applied mechanics, materials science, and applied mathematics."
"Compute a structure's deformations, internal forces, stresses, support reactions, velocity, accelerations, and stability."
"The results of the analysis are used to verify a structure's fitness for use, often precluding physical tests."
"Structural analysis is thus a key part of the engineering design of structures."
"Structural analysis is a branch of solid mechanics."
"Simplified models for solids like bars, beams, and shells."
"To determine the effect of loads on the physical structures and their components."
"All that must withstand loads, such as buildings, bridges, aircraft, and ships."
"Applied mechanics, materials science, and applied mathematics."
"A structure's deformations, internal forces, stresses, support reactions, velocity, accelerations, and stability."
"Verify a structure's fitness for use, often precluding physical tests."
"A key part of the engineering design of structures."
"Often precluding physical tests."
"Often differential equations in one spatial variable."
"Effect of loads on the physical structures and their components."
"Compute a structure's deformations, internal forces, stresses, support reactions, velocity, accelerations, and stability."