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Page 1 MATRIX METHOD OF ANALYSIS 1. DISPLACEMENT METHOD/STIFFNESS METHOD: In this method displacements at the joints are taken as unknowns and equation are expressed in terms of these unknown displacement. Additional joint equilibrium equations are developed to find the unknown displacement. This method is suitable when the Kinematic indeterminacy is less than the static indeterminacy. 1.1. Stiffness (k) It is the load required to produce unit displacement. Stiffness for various cases are as follows. (1) Axial stiffness (k11) = AE l (2) Transverse stiffness (k22) = 3 12EI l (3) Flexural stiffness (k33) = 4EI l (4) Torsional stiffness (k44) = GJ l 1.2. Procedure to Construct Stiffness Matrix To get first column of stiffness matrix, fix all the coordinates and give unit displacement at the 1 st coordinate and find forces developed at all other coordinates similarly to get the second column of stiffness matric apply unit displacement at coordinate 2 and find forces at all coordinates. The cantilever beam shown in the figure above will be subjected to three displacements (1), (2) and (3). When the unit displacement is given in direction of (1) i.e., horizontal deflection only, K11 = Force at (1) due to unit displacement at (1) = ???? ?? Page 2 MATRIX METHOD OF ANALYSIS 1. DISPLACEMENT METHOD/STIFFNESS METHOD: In this method displacements at the joints are taken as unknowns and equation are expressed in terms of these unknown displacement. Additional joint equilibrium equations are developed to find the unknown displacement. This method is suitable when the Kinematic indeterminacy is less than the static indeterminacy. 1.1. Stiffness (k) It is the load required to produce unit displacement. Stiffness for various cases are as follows. (1) Axial stiffness (k11) = AE l (2) Transverse stiffness (k22) = 3 12EI l (3) Flexural stiffness (k33) = 4EI l (4) Torsional stiffness (k44) = GJ l 1.2. Procedure to Construct Stiffness Matrix To get first column of stiffness matrix, fix all the coordinates and give unit displacement at the 1 st coordinate and find forces developed at all other coordinates similarly to get the second column of stiffness matric apply unit displacement at coordinate 2 and find forces at all coordinates. The cantilever beam shown in the figure above will be subjected to three displacements (1), (2) and (3). When the unit displacement is given in direction of (1) i.e., horizontal deflection only, K11 = Force at (1) due to unit displacement at (1) = ???? ?? K21 = Force at (2) due to unit displacement at (1) = 0 K31 = Force at (3) due to unit displacement at (1) = 0 When the unit displacement is given in direction of (2) i.e., vertical deflection only, K12 = Force at (1) due to unit displacement at (2) = 0 K22 = Force at (2) due to unit displacement at (2) = 2?? ?? ?? 3 K32 = Force at (3) due to unit displacement at (2) = - 6???? ?? 2 When the unit displacement is given in direction of (3) i.e., rotation only, K13 = Force at (1) due to unit displacement at (3) = 0 K23 = Force at (2) due to unit displacement at (3) = - 6???? ?? 2 K33 = Force at (3) due to unit displacement at (3) = 4???? ?? So, the stiffness matrix is ?? = [ ???? ?? 0 0 0 2???? ?? 3 - 6???? ?? 2 0 - 6???? ?? 2 4???? ?? ] 2. FLEXIBILITY MATRIX METHOD: In this method, forces are taken as unknown and equations are expressed in terms of these forces. Additional equation called compatibility condition are developed to find all the unknown forces. This method is suitable when the static indeterminacy is less than kinematic indeterminacy. 2.1. Flexibility (d) Flexibility is defined as the displacement produced due to unit force. It is the inverse of stiffness. Flexibility for various cases are as follows (a) Axial flexibility = 1 ???? ?? = ?? ???? (b) Transverse flexibility = 1 ???? ?? 3 = ?? 3 12???? Page 3 MATRIX METHOD OF ANALYSIS 1. DISPLACEMENT METHOD/STIFFNESS METHOD: In this method displacements at the joints are taken as unknowns and equation are expressed in terms of these unknown displacement. Additional joint equilibrium equations are developed to find the unknown displacement. This method is suitable when the Kinematic indeterminacy is less than the static indeterminacy. 1.1. Stiffness (k) It is the load required to produce unit displacement. Stiffness for various cases are as follows. (1) Axial stiffness (k11) = AE l (2) Transverse stiffness (k22) = 3 12EI l (3) Flexural stiffness (k33) = 4EI l (4) Torsional stiffness (k44) = GJ l 1.2. Procedure to Construct Stiffness Matrix To get first column of stiffness matrix, fix all the coordinates and give unit displacement at the 1 st coordinate and find forces developed at all other coordinates similarly to get the second column of stiffness matric apply unit displacement at coordinate 2 and find forces at all coordinates. The cantilever beam shown in the figure above will be subjected to three displacements (1), (2) and (3). When the unit displacement is given in direction of (1) i.e., horizontal deflection only, K11 = Force at (1) due to unit displacement at (1) = ???? ?? K21 = Force at (2) due to unit displacement at (1) = 0 K31 = Force at (3) due to unit displacement at (1) = 0 When the unit displacement is given in direction of (2) i.e., vertical deflection only, K12 = Force at (1) due to unit displacement at (2) = 0 K22 = Force at (2) due to unit displacement at (2) = 2?? ?? ?? 3 K32 = Force at (3) due to unit displacement at (2) = - 6???? ?? 2 When the unit displacement is given in direction of (3) i.e., rotation only, K13 = Force at (1) due to unit displacement at (3) = 0 K23 = Force at (2) due to unit displacement at (3) = - 6???? ?? 2 K33 = Force at (3) due to unit displacement at (3) = 4???? ?? So, the stiffness matrix is ?? = [ ???? ?? 0 0 0 2???? ?? 3 - 6???? ?? 2 0 - 6???? ?? 2 4???? ?? ] 2. FLEXIBILITY MATRIX METHOD: In this method, forces are taken as unknown and equations are expressed in terms of these forces. Additional equation called compatibility condition are developed to find all the unknown forces. This method is suitable when the static indeterminacy is less than kinematic indeterminacy. 2.1. Flexibility (d) Flexibility is defined as the displacement produced due to unit force. It is the inverse of stiffness. Flexibility for various cases are as follows (a) Axial flexibility = 1 ???? ?? = ?? ???? (b) Transverse flexibility = 1 ???? ?? 3 = ?? 3 12???? (c) Flexural flexibility = 1 4???? ?? = ?? 4???? (d) Torsional flexibility = 1 ???? ?? = ?? ???? 2.2. Procedure to construct Flexibility Matrix To get the first column of flexibility matrix, apply unit force at coordinate (1) and find displacement at all coordinates in the released structure. Similarly, to get II column of the flexibility matrix apply unit force at coordinate (2) and find displacement at all coordinates in the released structure. The cantilever beam shown in the figure above is subjected unit forces in three directions. When the unit force is applied in direction of (1) d11 = displacement at coordinate (1) due to unit load at coordinate (1) = ?? ???? d21 = displacement at coordinate (2) due to unit load at coordinate (1) = 0 d31 = displacement at coordinate (3) due to unit load at coordinate (1) = 0 When the unit load is applied in the direction of (2) d12 = displacement at coordinate (1) due to unit load at coordinate (2) = 0 d22 = displacement at coordinate (2) due to unit load at coordinate (2) = ?? 3 3???? d32 = displacement at coordinate (3) due to unit load at coordinate (2) = - ?? 2 2???? When the unit load is applied in the direction of (3) d13 = displacement at coordinate (1) due to unit load at coordinate (3) = 0 d23 = displacement at coordinate (2) due to unit load at coordinate (3) = - ?? 2 2???? d33 = displacement at coordinate (3) due to unit load at coordinate (3) = ?? ???? Page 4 MATRIX METHOD OF ANALYSIS 1. DISPLACEMENT METHOD/STIFFNESS METHOD: In this method displacements at the joints are taken as unknowns and equation are expressed in terms of these unknown displacement. Additional joint equilibrium equations are developed to find the unknown displacement. This method is suitable when the Kinematic indeterminacy is less than the static indeterminacy. 1.1. Stiffness (k) It is the load required to produce unit displacement. Stiffness for various cases are as follows. (1) Axial stiffness (k11) = AE l (2) Transverse stiffness (k22) = 3 12EI l (3) Flexural stiffness (k33) = 4EI l (4) Torsional stiffness (k44) = GJ l 1.2. Procedure to Construct Stiffness Matrix To get first column of stiffness matrix, fix all the coordinates and give unit displacement at the 1 st coordinate and find forces developed at all other coordinates similarly to get the second column of stiffness matric apply unit displacement at coordinate 2 and find forces at all coordinates. The cantilever beam shown in the figure above will be subjected to three displacements (1), (2) and (3). When the unit displacement is given in direction of (1) i.e., horizontal deflection only, K11 = Force at (1) due to unit displacement at (1) = ???? ?? K21 = Force at (2) due to unit displacement at (1) = 0 K31 = Force at (3) due to unit displacement at (1) = 0 When the unit displacement is given in direction of (2) i.e., vertical deflection only, K12 = Force at (1) due to unit displacement at (2) = 0 K22 = Force at (2) due to unit displacement at (2) = 2?? ?? ?? 3 K32 = Force at (3) due to unit displacement at (2) = - 6???? ?? 2 When the unit displacement is given in direction of (3) i.e., rotation only, K13 = Force at (1) due to unit displacement at (3) = 0 K23 = Force at (2) due to unit displacement at (3) = - 6???? ?? 2 K33 = Force at (3) due to unit displacement at (3) = 4???? ?? So, the stiffness matrix is ?? = [ ???? ?? 0 0 0 2???? ?? 3 - 6???? ?? 2 0 - 6???? ?? 2 4???? ?? ] 2. FLEXIBILITY MATRIX METHOD: In this method, forces are taken as unknown and equations are expressed in terms of these forces. Additional equation called compatibility condition are developed to find all the unknown forces. This method is suitable when the static indeterminacy is less than kinematic indeterminacy. 2.1. Flexibility (d) Flexibility is defined as the displacement produced due to unit force. It is the inverse of stiffness. Flexibility for various cases are as follows (a) Axial flexibility = 1 ???? ?? = ?? ???? (b) Transverse flexibility = 1 ???? ?? 3 = ?? 3 12???? (c) Flexural flexibility = 1 4???? ?? = ?? 4???? (d) Torsional flexibility = 1 ???? ?? = ?? ???? 2.2. Procedure to construct Flexibility Matrix To get the first column of flexibility matrix, apply unit force at coordinate (1) and find displacement at all coordinates in the released structure. Similarly, to get II column of the flexibility matrix apply unit force at coordinate (2) and find displacement at all coordinates in the released structure. The cantilever beam shown in the figure above is subjected unit forces in three directions. When the unit force is applied in direction of (1) d11 = displacement at coordinate (1) due to unit load at coordinate (1) = ?? ???? d21 = displacement at coordinate (2) due to unit load at coordinate (1) = 0 d31 = displacement at coordinate (3) due to unit load at coordinate (1) = 0 When the unit load is applied in the direction of (2) d12 = displacement at coordinate (1) due to unit load at coordinate (2) = 0 d22 = displacement at coordinate (2) due to unit load at coordinate (2) = ?? 3 3???? d32 = displacement at coordinate (3) due to unit load at coordinate (2) = - ?? 2 2???? When the unit load is applied in the direction of (3) d13 = displacement at coordinate (1) due to unit load at coordinate (3) = 0 d23 = displacement at coordinate (2) due to unit load at coordinate (3) = - ?? 2 2???? d33 = displacement at coordinate (3) due to unit load at coordinate (3) = ?? ???? So, the flexibility matrix is [?? ] = [ ?? ???? 0 0 0 ?? 3 3???? - ?? 2 2???? 0 - ?? 2 2???? ?? ???? ]Read More
FAQs on Short Notes: Matrix Method of Analysis - Short Notes for Civil Engineering - Civil Engineering (CE)
| 1. What is the matrix method of analysis in structural engineering? |  |
Ans. The matrix method of analysis in structural engineering is a mathematical technique used to analyze complex structures by representing the structure as a system of interconnected elements. This method involves creating a matrix equation that relates the external loads applied to the structure to the internal forces and displacements within the structure.
| 2. How is the matrix method of analysis different from other structural analysis methods? | |
Ans. The matrix method of analysis allows for the analysis of structures with a high degree of complexity and irregularity, as it can handle structures with multiple types of elements and loading conditions. Other methods, such as the force method or displacement method, may be limited in their ability to analyze such complex structures.
| 3. What are the advantages of using the matrix method of analysis in structural engineering? | |
Ans. Some advantages of using the matrix method of analysis include its ability to handle complex structures, its versatility in analyzing different types of loading conditions, its accuracy in predicting the behavior of structures, and its efficiency in solving large systems of equations.
| 4. Are there any limitations to the matrix method of analysis in structural engineering? | |
Ans. One limitation of the matrix method of analysis is that it can be computationally intensive, especially for large structures with a high number of elements. Additionally, the accuracy of the analysis is highly dependent on the input parameters and assumptions made during the modeling process.
| 5. How is the matrix method of analysis applied in real-world structural engineering projects? | |
Ans. The matrix method of analysis is commonly used in the design and analysis of buildings, bridges, and other structures to ensure their safety and stability. Structural engineers use specialized software programs to apply the matrix method and perform detailed analyses of complex structures to meet design requirements and codes.
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