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Fix some mistakes

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Akbar Rahman 2021-11-17 14:47:47 +00:00
parent 5538c471ba
commit 234a1f3e23
Signed by: alvierahman90
GPG Key ID: 20609519444A1269
1 changed files with 3 additions and 2 deletions
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mechanical/mmme1028_statics.md
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@ -42,6 +42,7 @@ Can be found here [here](./lecture_exercises/mmme1028_l1.2_exercises_2021-10-04.
<details> <details>
<summary> <summary>
### Example ### Example
Determine force $F$ and $x$ so that the body is in equilibrium. Determine force $F$ and $x$ so that the body is in equilibrium.
@ -506,13 +507,13 @@ $$ \epsilon_x = \frac {\Delta L}{L_0} $$
$$ \epsilon_y = \frac {\Delta w}{w_0} $$ $$ \epsilon_y = \frac {\Delta w}{w_0} $$
$$ \epsilon_z = \frac {\Delta t}{t_0} $$ $$ \epsilon_z = \frac {\Delta t}{t_0} $$
Poissons' ratio, $\nu$ (the greek letter _nu_, not v), is the ratio of lateral strain to axial Poisson's ratio, $\nu$ (the greek letter _nu_, not v), is the ratio of lateral strain to axial
strain: strain:
$$ \nu = \frac{\epsilon_y}{\epsilon_x} = \frac{\epsilon_z}{\epsilon_x} $$ $$ \nu = \frac{\epsilon_y}{\epsilon_x} = \frac{\epsilon_z}{\epsilon_x} $$
<details> <details>
</summary> <summary>
#### Example 1 #### Example 1