let i be Element of NAT ; :: thesis: for m, n being non empty Element of NAT
for F being PartFunc of ,
for G being PartFunc of ,
for x being Point of
for y being Element of REAL m st F = G & x = y holds
( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i )
let m, n be non empty Element of NAT ; :: thesis: for F being PartFunc of ,
for G being PartFunc of ,
for x being Point of
for y being Element of REAL m st F = G & x = y holds
( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i )
let F be PartFunc of ,; :: thesis: for G being PartFunc of ,
for x being Point of
for y being Element of REAL m st F = G & x = y holds
( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i )
let G be PartFunc of ,; :: thesis: for x being Point of
for y being Element of REAL m st F = G & x = y holds
( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i )
let x be Point of ; :: thesis: for y being Element of REAL m st F = G & x = y holds
( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i )
let y be Element of REAL m; :: thesis: ( F = G & x = y implies ( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i ) )
assume that
A1: F = G and
A2: x = y ; :: thesis: ( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i )
hence ( F is_partial_differentiable_in x,i iff G is_partial_differentiable_in y,i ) by A1, A2, Def13; :: thesis: verum