Points a1, a2, ... , ar in Rn are called affinely independent if whenever λ1a1 + ... + λrar = 0 with λ1 + ... + λr = 0 then λ1 = ... = λr = 0.
Prove that for such points the set { a2 - a1, a3 - a1, ... , ar - a1 } is linearly independent.
Prove that for such points the set of vectors { (a1, 1), (a2, 1), ... , (ar , 1) } in Rn × R is linearly independent.
Prove that there is a unique affine map taking any (n + 1) affinely independent points in Rn into any other (n + 1) affinely independent points.
Find a group of (n + 1) × (n + 1) matrices isomorphic to the affine group A(Rn).
[Look at Exercises 3 Question 3 to see the same result for I(Rn).]
Hence prove (again!) the result of Question 2, that there is a unique affine map taking any (n + 1) affinely independent points in Rn into any other (n + 1) affinely independent points.
If f is an affine map, prove that f maps the affine span of a1, a2, ... , ar to the affine span of f(a1), f(a2), ... , f(ar) and in fact, if λ1 + ... + λr = 1 then f(λ1a1 + ... + λrar) = λ1f(a1) + ... + λrf(ar). Deduce that an affine map takes the centroid of any set to the centroid of its image.
If ABCD is a quadrilateral in R2, prove that the midpoints of its sides form a parallelogram whose diagonals meet at the centroid of its vertices.
Is this true for a quadrilateral in R3 also?
If AB and A'B' are two line segments in R2, prove that there are two similarity transformations mapping AB to A'B' -- one of them direct (i.e. with linear part having positive determinant) and the other opposite.
[Hint: Consider squares with AB and A'B' as sides and consider affine maps taking one square to the other.]