Question

The projection of a vector on the three coordinate axes are (6, -3, 2) respectively. The direction cosines of the vector are:
$ {\text{A}}{\text{. 6, - 3, 2}} $
$  {\text{B}}{\text{. }}\dfrac{6}{5},{\text{ }}\dfrac{{ - 3}}{5},\dfrac{2}{5} $
$  {\text{C}}{\text{. }}\dfrac{6}{7},\dfrac{{ - 3}}{7},\dfrac{2}{7} $
$ {\text{D}}{\text{. }}\dfrac{{ - 6}}{7},\dfrac{{ - 3}}{7},\dfrac{2}{7} $

Answer 1

Hint: Go with the definition of the direction cosines. Take the under root sum of squares of the 3 projections and then divide the individual projection by that.

Complete step-by-step answer:

Direction cosines denote the cosines of the angles between the vector and the three coordinate axes. They are the contributions of each component (projection) of the basis to a unit vector in that direction.

So, if we have a vector $\vec a$ with its components along the three axes as ${a_x}\hat i,{a_y}\hat j,{a_z}\hat k$, then the direction cosines namely, l, m, n of the vector $\vec a$ would be-

$l = \cos \alpha = \dfrac{{{a_x}}}{{\sqrt {{a_x}^2 + {a_y}^2 + {a_z}^2} }}$ 

$m = \cos \beta = \dfrac{{{a_y}}}{{\sqrt {{a_x}^2 + {a_y}^2 + {a_z}^2} }}$ 

$n = \cos \gamma = \dfrac{{{a_z}}}{{\sqrt {{a_x}^2 + {a_y}^2 + {a_z}^2} }}$ 

So, following the above concept-

For the given vector the projections are- (6, -3, 2)

So, the direction cosines would be-

$l = \dfrac{{ 6}}{{\sqrt {{{\left( 6 \right)}^2} + {{\left( { - 3} \right)}^2} + {{\left( 2 \right)}^2}} }} = \dfrac{ 6}{7}$ 

$m = \dfrac{{ - 3}}{{\sqrt {{{\left( 6 \right)}^2} + {{\left( { - 3} \right)}^2} + {{\left( 2 \right)}^2}} }} = \dfrac{ - 3}{7}$ 

$n = \dfrac{{ 2}}{{\sqrt {{{\left( 6 \right)}^2} + {{\left( { - 3} \right)}^2} + {{\left( 2 \right)}^2}} }} = \dfrac{ 2}{7}$ 

Therefore, the correct option is C.

Note: Direction ratios are proportional to the direction cosines and are represented by the letters . Direction cosines are concerned with the unit vector while direction ratios are with their multiples.