Let the length of an edge of the cube be taken as unity and the vectors represented by OA, OB and OC (let the three coterminous edges of unit be `hati, hatj and hatk`, respectively). OR, OS and OT are the three diagonals of the three adjacent faces of the cube along which act the forces of magnitudes `a, 2a and 3a`, respectively. To find the vectors representing these forces, we will first find unit vectors in these directions and then multiply them by the corresponding given magnitudes of these forces.
Since `vec(OR) = hatj+hatk`, the unit vector along `OR` is `(1)/(sqrt(2))(hatj+hatk)`.
Hence, force `vec(F_(1))` of magnitude `a` along `OR` is given by
`" "vec(F_(1))=(a)/(sqrt(2))(hati+hatk)`
Similarly, force `vec(F_(1))` of magnitude 2a along OS is `(2a)/(sqrt(2))(hatk+hati)` and force `vec(F_(3))` of magnitude 3a along OT is `(3a)/(sqrt(2))(hati+hatj)`.
If `vecR` is their resultant, then
`" "vecR=vec(F_(1))+vec(F_(2))+vec(F_(3))`
`" " = (a)/(sqrt2) (hatj +hatk) + (2a)/(sqrt2) (hatk + hati) + (3a)/(sqrt2) (hati + hatj)`
`" " = (5a)/(sqrt2) hati + (4a)/(sqrt2) hatj + (3a)/(sqrt 2) hatk`
Again, `vec(OR) + vec(OS) + vec(OT) = hatj +hatk +hati +hatk +hati +hatj`
`" " = 2(hati +hatj +hatk)`
Also, `vec(OP) = vec(OT) + vec(TP) = (hati +hatj + hatk)" "(because vec(OT) = hati +hatj and vec(TP) = vec(OC) = hatk)`
`" " vec(OR) + vec(OS) + vec(OT) = 2 vec(OP) `
