A definition of dot product (wich is an inner product) is

**x** . **y** = |**x**| * |**y**| * cos(a)

Where a is the smallest angle between **x** and **y**.

It is easy to see that **x** . **y** = 0, if a=90 deg (pi rad).

This means that if you have a fixed normal vector **w**, a hyperplane given by:

**x** . **w** = 0

is the set of all points that **x** can "point at" given that **x** has to be orthogonal to **w**.

Now, a hyperplane given by:

**x** . **w** + b = 0

is the set of all points that **x** can "point at" such that **x** . **w** is a constant. As **x** gets longer, |**x**| increases, the angle, a, has to get closer to 90 deg (pi rad), cos(a) decreases, to produce the same constant result. If you however take **x** pointing in the exact opposite direction of **w**, cos(a) = -1 and |**x**| = b (provided that **w** is of unit length).

It turns out that the plane given of this set of points is parallell to **x** . **w** = 0, and shifted in space the distance -b (in the direction of **w**) still given that **w** is of unit length.

This answer is probably not going to help the op, but hopefully someone else will benefit from it.

xis the"variable", i.e the plane is the set of all pointsx(x is a vector) that satisfy the equation w.x+b=0 – Amro Oct 7 '09 at 10:30