13. Planes in space (page 2)

13. Planes in space


The Cartesian equation of a plane	Page 2 of 2

Suppose that P₀ has coordinates x₀,y₀,z₀ and n has components a,b,c.

Let P, with coordinates x,y,z, be an arbitrary point on the plane.

The position vectors of P₀ and P are

-O-P--> = r = x i + y j + z k 0 0 0 0 0

and

-OP--> = r = xi + yj + zk.

Substituting

r = xi + yj + zk, r0 = x0i + y0j + z0k n = ai + bj + ck

into the vector equation, we obtain

( ) (x- x0)i + (y - y0)j + (z - z0)k · (ai + bj + ck) = 0

which, when multiplied out, gives

a(x - x0) + b(y - y0) + c(z- z0) = 0.

This is called a Cartesian equation of the plane.

It simplifies to

ax + by + cz = d

where d is the constant ax₀ + by₀ + cz₀.

An equation of the form

ax + by + cz = d

where a,b,c and d are constants and not all a,b,c are zero, can be taken to be an equation of a plane in space.

The coefficients a, b and c are the components of a normal vector

n = ai + bj + ck

for the plane described by the equation.

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