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 Page 3


 
 
 
                                                         
 
 
                                                         
 
 
667 . 1
6
4
4
4
11
= + =
EI EI
k 
 
EI
EI
k 5 . 0
4
2
21
= = 
 
EI
EI
k 166 . 0
6 6
6
31
- =
×
- =      (4) 
 
Similarly, apply a unit rotation along and calculate reactions corresponding to 
three degrees of freedom (see Fig.23.5e) 
2
u
 
EI k 5 . 0
12
= 
 
EI k =
22
 
 
0
32
= k        (5) 
 
Apply a unit displacement along and calculate joint reactions corresponding to 
unknown displacements in the kinematically determinate structure. 
3
u
                                                         
Page 4


 
 
 
                                                         
 
 
                                                         
 
 
667 . 1
6
4
4
4
11
= + =
EI EI
k 
 
EI
EI
k 5 . 0
4
2
21
= = 
 
EI
EI
k 166 . 0
6 6
6
31
- =
×
- =      (4) 
 
Similarly, apply a unit rotation along and calculate reactions corresponding to 
three degrees of freedom (see Fig.23.5e) 
2
u
 
EI k 5 . 0
12
= 
 
EI k =
22
 
 
0
32
= k        (5) 
 
Apply a unit displacement along and calculate joint reactions corresponding to 
unknown displacements in the kinematically determinate structure. 
3
u
                                                         
E
L
EI
k 166 . 0
6
2
13
- = - = 
 
0
23
= k 
 
EI
EI
k 056 . 0
6
12
3
33
= =     (6) 
 
Finally applying the principle of superposition of joint forces, yields 
 
11
22
33
6 1.667 0.5 0.166
24 0.5 1 0
12 0.166 0 0.056
F u
F EI u
F u
- ?? ? ? ?? ? ?
?? ? ? ? ?? ?
=- +
?? ? ? ? ?? ?
?? ? ? ? ?? ?
-
?? ? ? ?? ? ?
 
 
Now, 
 
?
?
?
?
?
?
?
?
?
?
=
?
?
?
?
?
?
?
?
?
?
0
0
0
3
2
1
F
F
F
 as there are no loads applied along  and .Thus the  
2 1
,u u
3
u
 
unknown displacements are, 
 
1
1
2
3
10.5 0.166 6
1
0.5 1 0 24
0.166 0 0.056 24
u
u
EI
u
-
- ????
?? ? ?
??
=- -
?? ? ?
?
?? ? ?
?? --
?? ??
??
?
??
  (7) 
 
Solving 
 
1
18.996
u
EI
=
 
 
2
14.502
u
EI
=
 
 
3
270.587
u
EI
=-
      (8) 
 
 
                                                         
Page 5


 
 
 
                                                         
 
 
                                                         
 
 
667 . 1
6
4
4
4
11
= + =
EI EI
k 
 
EI
EI
k 5 . 0
4
2
21
= = 
 
EI
EI
k 166 . 0
6 6
6
31
- =
×
- =      (4) 
 
Similarly, apply a unit rotation along and calculate reactions corresponding to 
three degrees of freedom (see Fig.23.5e) 
2
u
 
EI k 5 . 0
12
= 
 
EI k =
22
 
 
0
32
= k        (5) 
 
Apply a unit displacement along and calculate joint reactions corresponding to 
unknown displacements in the kinematically determinate structure. 
3
u
                                                         
E
L
EI
k 166 . 0
6
2
13
- = - = 
 
0
23
= k 
 
EI
EI
k 056 . 0
6
12
3
33
= =     (6) 
 
Finally applying the principle of superposition of joint forces, yields 
 
11
22
33
6 1.667 0.5 0.166
24 0.5 1 0
12 0.166 0 0.056
F u
F EI u
F u
- ?? ? ? ?? ? ?
?? ? ? ? ?? ?
=- +
?? ? ? ? ?? ?
?? ? ? ? ?? ?
-
?? ? ? ?? ? ?
 
 
Now, 
 
?
?
?
?
?
?
?
?
?
?
=
?
?
?
?
?
?
?
?
?
?
0
0
0
3
2
1
F
F
F
 as there are no loads applied along  and .Thus the  
2 1
,u u
3
u
 
unknown displacements are, 
 
1
1
2
3
10.5 0.166 6
1
0.5 1 0 24
0.166 0 0.056 24
u
u
EI
u
-
- ????
?? ? ?
??
=- -
?? ? ?
?
?? ? ?
?? --
?? ??
??
?
??
  (7) 
 
Solving 
 
1
18.996
u
EI
=
 
 
2
14.502
u
EI
=
 
 
3
270.587
u
EI
=-
      (8) 
 
 
                                                         
Summary 
The flexibility coefficient and stiffness coefficients are defined in this section. 
Construction of stiffness matrix for a simple member is explained. A few simple 
problems are solved by the direct stiffness method. The difference between the 
slope-deflection method and the direct stiffness method is clearly brought out. 
 
                                                         
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FAQs on Introduction: The Direct Stiffness Method - 4 - Structural Analysis - Civil Engineering (CE)

1. What is the Direct Stiffness Method?
Ans. The Direct Stiffness Method is a numerical technique used in structural analysis to calculate displacements, reactions, and internal forces in a structure. It involves dividing the structure into smaller elements and representing them with stiffness matrices. By assembling these matrices and applying boundary conditions, the method allows for the solution of complex structural problems.
2. How does the Direct Stiffness Method work?
Ans. The Direct Stiffness Method works by first dividing the structure into smaller elements, such as beams or trusses. Each element is then represented by a stiffness matrix, which relates the element's displacements to the applied loads. These stiffness matrices are then assembled to form the global stiffness matrix of the entire structure. By applying boundary conditions and solving the resulting system of equations, the displacements, reactions, and internal forces of the structure can be determined.
3. What are the advantages of using the Direct Stiffness Method?
Ans. The Direct Stiffness Method offers several advantages in structural analysis. Firstly, it can handle complex geometries and boundary conditions, making it suitable for a wide range of structural problems. Additionally, it provides accurate and precise results when compared to other approximate methods. Moreover, the method can be easily implemented in computer programs, allowing for efficient and automated analysis of structures.
4. What are the limitations of the Direct Stiffness Method?
Ans. While the Direct Stiffness Method is a powerful technique, it also has some limitations. One limitation is that it requires dividing the structure into smaller elements, which can be time-consuming and tedious for complex structures. Another limitation is that it assumes linear behavior of the materials and neglects non-linear effects, which may limit its applicability in certain situations. Additionally, the method may be computationally demanding for large-scale structures, requiring significant computational resources.
5. How is the Direct Stiffness Method different from other structural analysis methods?
Ans. The Direct Stiffness Method differs from other structural analysis methods in several ways. Unlike approximate methods, such as the method of sections or the moment distribution method, the Direct Stiffness Method provides more accurate and precise results by considering the entire structure's behavior. It also allows for the analysis of complex geometries and boundary conditions that may not be easily solvable using other methods. Additionally, the Direct Stiffness Method can be easily implemented in computer programs, enabling automated analysis and efficient handling of large-scale structures.
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