Answer:
B = 2.67i - 0.53j
Explanation:
In order to find the vector B, you first take into account the following formula:
[tex]\vec{A}\cdot\vec{B}=ABcos\theta[/tex] (1)
where:
A = 2.00i + 3.00j
B = ?
θ: angle between vectors A and B = 45.0°
You use the fact that the dot product between vectors A and B is 7.00.
You calculate the magnitude of A vector as follow:
[tex]A=\sqrt{(2.00)^2+(3.00)^2}=3.60[/tex]
Then, you solve the equation (1) for the magnitude of B:
[tex]B=\frac{\vec{A}\cdot\vec{B}}{Acos\theta}=\frac{7.00}{3.60cos(45\°)}=2.74[/tex]
Next, you can consider that the A vector is the x axis of the coordinate system, to calculate the components of B. This means that the coordinate system is rotated an angle equivalent to the angle of A respect to the x axis.
With the previous assumption you have that the components of B are:
[tex]B_x=Bcos\theta=(2.74)cos45\°=1.93\\\\B_y=Bsin45\°=(2.74)sin45\°=1.93[/tex]
The vector B is:
B = 1.93i + 1.93j
Next, it is necessary to rotate again the coordinate system to its original position. For that, you calculate the angle of A:
[tex]\alpha=tan^{-1}(\frac{3.00}{2.00})=56.30[/tex]
In order to calculate the real components of B, you rotate the system 56.30°, by using the following relation:
[tex]B_x'=B_xcos\alpha+B_ysin\alpha\\\\B_x'=1.93cos(56.30\°)+1.93sin(56.30\°)=2.67\\\\B_y'=-B_xsin\alpha+B_ycos\alpha\\\\B_y'=-1.93sin(56.30\°)+1.93cos(56.30\°)=-0.53[/tex]
The vector B is:
B = 2.67i - 0.53j
