let u be Element of REAL 3; :: thesis: for f being PartFunc of (REAL 3),REAL holds
( f is_hpartial_differentiable`32_in u iff pdiff1 f,3 is_partial_differentiable_in u,2 )
let f be PartFunc of (REAL 3),REAL ; :: thesis: ( f is_hpartial_differentiable`32_in u iff pdiff1 f,3 is_partial_differentiable_in u,2 )
thus ( f is_hpartial_differentiable`32_in u implies pdiff1 f,3 is_partial_differentiable_in u,2 ) :: thesis: ( pdiff1 f,3 is_partial_differentiable_in u,2 implies f is_hpartial_differentiable`32_in u )
proof
assume f is_hpartial_differentiable`32_in u ; :: thesis: pdiff1 f,3 is_partial_differentiable_in u,2
then consider x0, y0, z0 being Real such that
A1: ( u = <*x0,y0,z0*> & ex N being Neighbourhood of y0 st
( N c= dom (SVF1 2,(pdiff1 f,3),u) & ex L being LINEAR ex R being REST st
for y being Real st y in N holds
((SVF1 2,(pdiff1 f,3),u) . y) - ((SVF1 2,(pdiff1 f,3),u) . y0) = (L . (y - y0)) + (R . (y - y0)) ) ) by Def6ForSecondOrder;
thus pdiff1 f,3 is_partial_differentiable_in u,2 by A1, PDIFF_4:14; :: thesis: verum
end;
assume pdiff1 f,3 is_partial_differentiable_in u,2 ; :: thesis: f is_hpartial_differentiable`32_in u
then consider x0, y0, z0 being Real such that
A4: ( u = <*x0,y0,z0*> & ex N being Neighbourhood of y0 st
( N c= dom (SVF1 2,(pdiff1 f,3),u) & ex L being LINEAR ex R being REST st
for y being Real st y in N holds
((SVF1 2,(pdiff1 f,3),u) . y) - ((SVF1 2,(pdiff1 f,3),u) . y0) = (L . (y - y0)) + (R . (y - y0)) ) ) by PDIFF_4:14;
thus f is_hpartial_differentiable`32_in u by A4, Def6ForSecondOrder; :: thesis: verum