Respuesta :
Answer:
[tex]F_p = < - \sqrt{3} , -3 >\\\\F_o = < \sqrt{3} , -1 >[/tex]
Step-by-step explanation:
- A plane is oriented in a Cartesian coordinate system such that it makes an angle of ( π / 3 ) with the positive x - axis.
- A force ( F ) is directed along the y-axis as a vector < 0 , - 4 >
- We are to determine the the components of force ( F ) parallel and normal to the defined plane.
- We will denote two unit vectors: ( [tex]u_p[/tex] ) parallel to plane and ( [tex]u_o[/tex] ) orthogonal to the defined plane. We will define the two unit vectors in ( x - y ) plane as follows:
- The unit vector ( [tex]u_p[/tex] ) parallel to the defined plane makes an angle of ( 30° ) with the positive y-axis and an angle of ( π / 3 = 60° ) with the x-axis. We will find the projection of the vector onto the x and y axes as follows:
[tex]u_o[/tex] = < cos ( 60° ) , cos ( 30° ) >
[tex]u_o = < \frac{1}{2} , \frac{\sqrt{3} }{2} >[/tex]
- Similarly, the unit vector ( [tex]u_o[/tex] ) orthogonal to plane makes an angle of ( π / 3 ) with the positive x - axis and angle of ( π / 6 ) with the y-axis in negative direction. We will find the projection of the vector onto the x and y axes as follows:
[tex]u_p = < cos ( \frac{\pi }{6} ) , - cos ( \frac{\pi }{3} ) >\\\\u_p = < \frac{\sqrt{3} }{2} , -\frac{1}{2} >\\[/tex]
- To find the projection of force ( F ) along and normal to the plane we will apply the dot product formulation:
- The Force vector parallel to the plane ( [tex]F_p[/tex] ) would be:
[tex]F_p = u_p(F . u_p)\\\\F_p = < \frac{1}{2} , \frac{\sqrt{3} }{2} > [ < 0 , - 4 > . < \frac{1}{2} , \frac{\sqrt{3} }{2} > ]\\\\F_p = < \frac{1}{2} , \frac{\sqrt{3} }{2} > [ -2\sqrt{3} ]\\\\F_p = < -\sqrt{3} , -3 >\\[/tex]
- Similarly, to find the projection of force ( [tex]F_o[/tex] ) normal to the plane we again employ the dot product formulation with normal unit vector ( [tex]u_o[/tex] ) as follows:
[tex]F_o = u_o ( F . u_o )\\\\F_o = < \frac{\sqrt{3} }{2} , - \frac{1}{2} > [ < 0 , - 4 > . < \frac{\sqrt{3} }{2} , - \frac{1}{2} > ] \\\\F_o = < \frac{\sqrt{3} }{2} , - \frac{1}{2} > [ 2 ] \\\\F_o = < \sqrt{3} , - 1 >[/tex]
- To prove that the projected forces ( [tex]F_o[/tex] ) and ( [tex]F_p[/tex] ) are correct we will apply the vector summation of the two orthogonal vector which must equal to the original vector < 0 , - 4 >
[tex]F = F_o + F_p\\\\< 0 , - 4 > = < \sqrt{3}, -1 > + < -\sqrt{3}, -3 > \\\\< 0 , - 4 > = < \sqrt{3} - \sqrt{3} , -1 - 3 > \\\\< 0 , - 4 > = < 0 , - 4 >[/tex] .. proven
