Let G(1),G(2),G(3) be the centroids of t...

Let `G_(1),G_(2),G_(3)` be the centroids of the triangular faces `OBC, OCA, OAB` of a tetrahedron `OABC`. If `V_(1)` denote the volume of the tetrahedron `OABC` and `V_(2)` that of the parallelopiped with `OG_(1),OG_(2),OG_(3)` as three concurrent edges, then

`4V_(1)=9V_(2)`

`9V_(1)=4V_(2)`

`3V_(1)=2V_(2)`

`3V_(2)=2V_(1)`

Text Solution

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The correct Answer is:

Taking `O` as the origin let the position vectors of `A,B` and `C` be `veca,vecb` and `vecc` respectively. Thenthe position vectors of `G_(1),G_(2)` and `G_(3)` are `(vecb+vecc)/3,(vecc+veca)/3` and `(veca+vecb)/3` respectively.
`:.V_(1)=1/6[(veca,vecb, vecc)]` and `V_(2)=[(vec(OG_(1)),vec(OG_(2)),vec(OG_(3)))]`
`V_(2)=[(vec(OG_(1)),vec(OG_(2)),vec(OG_(3)))]`
`implies V_(2)=[((vecb+vecc)/3,(vecc+veca)/3,(veca+vecb)/3)]`
`impliesV_(2)=1/27[(vecb+vecc,vecc+veca,veca+vecb)]`
`impliesV_(2)=2/27[(veca,vecb,vecc)]impliesV_(2)=2/27xx6V_(1)=9V_(2)=4V_(1)`

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