set F = the PolytopsF of p;
per cases ( k < - 1 or k = - 1 or ( - 1 < k & k < dim p ) or k = dim p or k > dim p ) by XXREAL_0:1;
suppose A1: k < - 1 ; :: thesis: ex b1 being finite set st
( ( k < - 1 implies b1 = {} ) & ( k = - 1 implies b1 = {{} } ) & ( - 1 < k & k < dim p implies b1 = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies b1 = {p} ) & ( k > dim p implies b1 = {} ) )
take {} ; :: thesis: ( ( k < - 1 implies {} = {} ) & ( k = - 1 implies {} = {{} } ) & ( - 1 < k & k < dim p implies {} = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {} = {p} ) & ( k > dim p implies {} = {} ) )
thus ( ( k < - 1 implies {} = {} ) & ( k = - 1 implies {} = {{} } ) & ( - 1 < k & k < dim p implies {} = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {} = {p} ) & ( k > dim p implies {} = {} ) ) by A1; :: thesis: verum
end;
suppose A2: k = - 1 ; :: thesis: ex b1 being finite set st
( ( k < - 1 implies b1 = {} ) & ( k = - 1 implies b1 = {{} } ) & ( - 1 < k & k < dim p implies b1 = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies b1 = {p} ) & ( k > dim p implies b1 = {} ) )
take {{} } ; :: thesis: ( ( k < - 1 implies {{} } = {} ) & ( k = - 1 implies {{} } = {{} } ) & ( - 1 < k & k < dim p implies {{} } = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {{} } = {p} ) & ( k > dim p implies {{} } = {} ) )
thus ( ( k < - 1 implies {{} } = {} ) & ( k = - 1 implies {{} } = {{} } ) & ( - 1 < k & k < dim p implies {{} } = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {{} } = {p} ) & ( k > dim p implies {{} } = {} ) ) by A2; :: thesis: verum
end;
suppose A3: ( - 1 < k & k < dim p ) ; :: thesis: ex b1 being finite set st
( ( k < - 1 implies b1 = {} ) & ( k = - 1 implies b1 = {{} } ) & ( - 1 < k & k < dim p implies b1 = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies b1 = {p} ) & ( k > dim p implies b1 = {} ) )
(- 1) + 1 = 0 ;
then 0 <= k by A3, INT_1:20;
then reconsider k = k as Element of NAT by INT_1:16;
set n = k + 1;
reconsider Fn = the PolytopsF of p . (k + 1) as FinSequence ;
take rng Fn ; :: thesis: ( ( k < - 1 implies rng Fn = {} ) & ( k = - 1 implies rng Fn = {{} } ) & ( - 1 < k & k < dim p implies rng Fn = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies rng Fn = {p} ) & ( k > dim p implies rng Fn = {} ) )
thus ( ( k < - 1 implies rng Fn = {} ) & ( k = - 1 implies rng Fn = {{} } ) & ( - 1 < k & k < dim p implies rng Fn = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies rng Fn = {p} ) & ( k > dim p implies rng Fn = {} ) ) by A3; :: thesis: verum
end;
suppose A4: k = dim p ; :: thesis: ex b1 being finite set st
( ( k < - 1 implies b1 = {} ) & ( k = - 1 implies b1 = {{} } ) & ( - 1 < k & k < dim p implies b1 = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies b1 = {p} ) & ( k > dim p implies b1 = {} ) )
take {p} ; :: thesis: ( ( k < - 1 implies {p} = {} ) & ( k = - 1 implies {p} = {{} } ) & ( - 1 < k & k < dim p implies {p} = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {p} = {p} ) & ( k > dim p implies {p} = {} ) )
thus ( ( k < - 1 implies {p} = {} ) & ( k = - 1 implies {p} = {{} } ) & ( - 1 < k & k < dim p implies {p} = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {p} = {p} ) & ( k > dim p implies {p} = {} ) ) by A4; :: thesis: verum
end;
suppose A5: k > dim p ; :: thesis: ex b1 being finite set st
( ( k < - 1 implies b1 = {} ) & ( k = - 1 implies b1 = {{} } ) & ( - 1 < k & k < dim p implies b1 = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies b1 = {p} ) & ( k > dim p implies b1 = {} ) )
take {} ; :: thesis: ( ( k < - 1 implies {} = {} ) & ( k = - 1 implies {} = {{} } ) & ( - 1 < k & k < dim p implies {} = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {} = {p} ) & ( k > dim p implies {} = {} ) )
thus ( ( k < - 1 implies {} = {} ) & ( k = - 1 implies {} = {{} } ) & ( - 1 < k & k < dim p implies {} = rng (the PolytopsF of p . (k + 1)) ) & ( k = dim p implies {} = {p} ) & ( k > dim p implies {} = {} ) ) by A5; :: thesis: verum
end;
end;