A set $A$ is said to be an affine set if for any two distinct points, the line passing through these points lie in the set $A$.
Note −
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$S$ is an affine set if and only if it contains every affine combination of its points.
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Empty and singleton sets are both affine and convex set.
For example, solution of a linear equation is an affine set.
Proof
Let S be the solution of a linear equation.
By definition, $S=left { x in mathbb{R}^n:Ax=b right }$
Let $x_1,x_2 in SRightarrow Ax_1=b$ and $Ax_2=b$
To prove : $Aleft [ theta x_1+left ( 1-theta right )x_2 right ]=b, forall theta inleft ( 0,1 right )$
$Aleft [ theta x_1+left ( 1-theta right )x_2 right ]=theta Ax_1+left ( 1-theta right )Ax_2=theta b+left ( 1-theta right )b=b$
Thus S is an affine set.
Theorem
If $C$ is an affine set and $x_0 in C$, then the set $V= C-x_0=left { x-x_0:x in C right }$ is a subspace of C.
Proof
Let $x_1,x_2 in V$
To show: $alpha x_1+beta x_2 in V$ for some $alpha,beta$
Now, $x_1+x_0 in C$ and $x_2+x_0 in C$ by definition of V
Now, $alpha x_1+beta x_2+x_0=alpha left ( x_1+x_0 right )+beta left ( x_2+x_0 right )+left ( 1-alpha -beta right )x_0$
But $alpha left ( x_1+x_0 right )+beta left ( x_2+x_0 right )+left ( 1-alpha -beta right )x_0 in C$ because C is an affine set.
Therefore, $alpha x_1+beta x_2 in V$
Hence proved.
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