The Cartesian equation of the plane ` vec r=(1+lambda-mu) hat i+(2-lambda) hat j+(3-2lambda+2mu) hat k` is

Find the Cartesian equation of the following planes: r.(hat(i)+hat(j)-hat(k))=0

Find the Cartesian equation of the following planes: r.(2hat(i)+3hat(j)-4hat(k))=1

Find the vector and cartesian equations of a plane containing the two lines vec(r) = (2 hat(i) + hat(j) - 3 hat(k)) + lambda(hat(i) + 2 hat(j) + 5 hat(k)) and vec(r) = (3hat(i) + 3 hat(j) + 2 hat(k)) + lambda (3 hat(i) - 2 hat(j) + 5 hat(k)) . Also show that the line vec(r) = (2 hat(i) + 5 hat(j) + 2 hat(k)) + p (3 hat(i) - 2 hat(j) + 5 hat(k)) lies in the plane.

Find the Cartesian equation of the following planes: r.[(s-2t)hat(i)+(3-t)hat(j)+(2s+t)hat(k)]=15

Find the vector and Cartesian equations of the planes. That passes through the point (1, 0, -2) and the normal to the plane is hat(i)-2hat(j)+hat(k) .

Find the vector and Cartesian equations of the planes. That passes through the point (1, 4, 6) and the normal to the plane is hat(i)-2hat(j)+hat(k) .

Equation of the plane containing the line vec r = i+j + lambda (2i+j+4k) is

Find the distance of the point (2,12,5) from the point of intersection of the lines vec(r) = (2 hat(i) - 4 hat(j) + 2 hat(k)) + lambda (3 hat(i) + 4 hat(j) + 2 hat(k)) and the plane r * (hat(i) - 2 hat(j) + hat(k)) = 0