let x0, y0, z0 be Real; for u being Element of REAL 3
for f being PartFunc of (REAL 3),REAL st u = <*x0,y0,z0*> & f is_hpartial_differentiable`22_in u holds
SVF1 (2,(pdiff1 (f,2)),u) is_differentiable_in y0
let u be Element of REAL 3; for f being PartFunc of (REAL 3),REAL st u = <*x0,y0,z0*> & f is_hpartial_differentiable`22_in u holds
SVF1 (2,(pdiff1 (f,2)),u) is_differentiable_in y0
let f be PartFunc of (REAL 3),REAL; ( u = <*x0,y0,z0*> & f is_hpartial_differentiable`22_in u implies SVF1 (2,(pdiff1 (f,2)),u) is_differentiable_in y0 )
assume that
A1:
u = <*x0,y0,z0*>
and
A2:
f is_hpartial_differentiable`22_in u
; SVF1 (2,(pdiff1 (f,2)),u) is_differentiable_in y0
consider x1, y1, z1 being Real such that
A3:
( u = <*x1,y1,z1*> & ex N being Neighbourhood of y1 st
( N c= dom (SVF1 (2,(pdiff1 (f,2)),u)) & ex L being LinearFunc ex R being RestFunc st
for y being Real st y in N holds
((SVF1 (2,(pdiff1 (f,2)),u)) . y) - ((SVF1 (2,(pdiff1 (f,2)),u)) . y1) = (L . (y - y1)) + (R . (y - y1)) ) )
by A2;
y0 = y1
by A1, A3, FINSEQ_1:78;
hence
SVF1 (2,(pdiff1 (f,2)),u) is_differentiable_in y0
by A3, FDIFF_1:def 4; verum