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In mathematics , the Pincherle derivative [1]
T
′
{\displaystyle T'}
linear operator
T
:
K
[
x
]
→
K
[
x
]
{\displaystyle T:\mathbb {K} [x]\to \mathbb {K} [x]}
vector space of polynomials in the variable x over a field
K
{\displaystyle \mathbb {K} }
commutator of
T
{\displaystyle T}
x in the algebra of endomorphisms
End
(
K
[
x
]
)
{\displaystyle \operatorname {End} (\mathbb {K} [x])}
T
′
{\displaystyle T'}
T
′
:
K
[
x
]
→
K
[
x
]
{\displaystyle T':\mathbb {K} [x]\to \mathbb {K} [x]}
T
′
:=
[
T
,
x
]
=
T
x
−
x
T
=
−
ad
(
x
)
T
,
{\displaystyle T':=[T,x]=Tx-xT=-\operatorname {ad} (x)T,\,}
(for the origin of the
ad
{\displaystyle \operatorname {ad} }
adjoint representation ) so that
T
′
{
p
(
x
)
}
=
T
{
x
p
(
x
)
}
−
x
T
{
p
(
x
)
}
∀
p
(
x
)
∈
K
[
x
]
.
{\displaystyle T'\{p(x)\}=T\{xp(x)\}-xT\{p(x)\}\qquad \forall p(x)\in \mathbb {K} [x].}
This concept is named after the Italian mathematician Salvatore Pincherle (1853–1936).
Properties [ ] The Pincherle derivative, like any commutator , is a derivation , meaning it satisfies the sum and products rules: given two linear operators
S
{\displaystyle S}
T
{\displaystyle T}
End
(
K
[
x
]
)
,
{\displaystyle \operatorname {End} \left(\mathbb {K} [x]\right),}
(
T
+
S
)
′
=
T
′
+
S
′
{\displaystyle (T+S)^{\prime }=T^{\prime }+S^{\prime }}
(
T
S
)
′
=
T
′
S
+
T
S
′
{\displaystyle (TS)^{\prime }=T^{\prime }\!S+TS^{\prime }}
T
S
=
T
∘
S
{\displaystyle TS=T\circ S}
composition of operators .One also has
[
T
,
S
]
′
=
[
T
′
,
S
]
+
[
T
,
S
′
]
{\displaystyle [T,S]^{\prime }=[T^{\prime },S]+[T,S^{\prime }]}
[
T
,
S
]
=
T
S
−
S
T
{\displaystyle [T,S]=TS-ST}
Lie bracket , which follows from the Jacobi identity .
The usual derivative , D = d /dx , is an operator on polynomials. By straightforward computation, its Pincherle derivative is
D
′
=
(
d
d
x
)
′
=
Id
K
[
x
]
=
1.
{\displaystyle D'=\left({d \over {dx}}\right)'=\operatorname {Id} _{\mathbb {K} [x]}=1.}
This formula generalizes to
(
D
n
)
′
=
(
d
n
d
x
n
)
′
=
n
D
n
−
1
,
{\displaystyle (D^{n})'=\left({{d^{n}} \over {dx^{n}}}\right)'=nD^{n-1},}
by induction . This proves that the Pincherle derivative of a differential operator
∂
=
∑
a
n
d
n
d
x
n
=
∑
a
n
D
n
{\displaystyle \partial =\sum a_{n}{{d^{n}} \over {dx^{n}}}=\sum a_{n}D^{n}}
is also a differential operator, so that the Pincherle derivative is a derivation of
Diff
(
K
[
x
]
)
{\displaystyle \operatorname {Diff} (\mathbb {K} [x])}
When
K
{\displaystyle \mathbb {K} }
characteristic zero, the shift operator
S
h
(
f
)
(
x
)
=
f
(
x
+
h
)
{\displaystyle S_{h}(f)(x)=f(x+h)\,}
can be written as
S
h
=
∑
n
≥
0
h
n
n
!
D
n
{\displaystyle S_{h}=\sum _{n\geq 0}{{h^{n}} \over {n!}}D^{n}}
by the Taylor formula . Its Pincherle derivative is then
S
h
′
=
∑
n
≥
1
h
n
(
n
−
1
)
!
D
n
−
1
=
h
⋅
S
h
.
{\displaystyle S_{h}'=\sum _{n\geq 1}{{h^{n}} \over {(n-1)!}}D^{n-1}=h\cdot S_{h}.}
In other words, the shift operators are eigenvectors of the Pincherle derivative, whose spectrum is the whole space of scalars
K
{\displaystyle \mathbb {K} }
If T is shift-equivariant , that is, if T commutes with S h
[
T
,
S
h
]
=
0
{\displaystyle [T,S_{h}]=0}
[
T
′
,
S
h
]
=
0
{\displaystyle [T',S_{h}]=0}
T
′
{\displaystyle T'}
h
{\displaystyle h}
The "discrete-time delta operator"
(
δ
f
)
(
x
)
=
f
(
x
+
h
)
−
f
(
x
)
h
{\displaystyle (\delta f)(x)={{f(x+h)-f(x)} \over h}}
is the operator
δ
=
1
h
(
S
h
−
1
)
,
{\displaystyle \delta ={1 \over h}(S_{h}-1),}
whose Pincherle derivative is the shift operator
δ
′
=
S
h
{\displaystyle \delta '=S_{h}}
See also [ ] References [ ] External links [ ] 
![{\displaystyle T:\mathbb {K} [x]\to \mathbb {K} [x]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/3258999b37e031c221d4fe0907c0aefb540ebc1a)
![{\displaystyle \operatorname {End} (\mathbb {K} [x])}](https://wikimedia.org/api/rest_v1/media/math/render/svg/e54c48522eacff130c49470eb25962a1274efcee)
![{\displaystyle T':\mathbb {K} [x]\to \mathbb {K} [x]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/1004d559f5f528d5450e605804e987f11fbf37e7)
![{\displaystyle T':=[T,x]=Tx-xT=-\operatorname {ad} (x)T,\,}](https://wikimedia.org/api/rest_v1/media/math/render/svg/adeaa560041ded4e7cc9ef6d1ee77550949a01d8)
![{\displaystyle T'\{p(x)\}=T\{xp(x)\}-xT\{p(x)\}\qquad \forall p(x)\in \mathbb {K} [x].}](https://wikimedia.org/api/rest_v1/media/math/render/svg/25baff00a3c5ca6de0647d4daf76c6622b41b421)
![{\displaystyle \operatorname {End} \left(\mathbb {K} [x]\right),}](https://wikimedia.org/api/rest_v1/media/math/render/svg/c266996663f11923aac7dba51e34ae5f392f77b2)
![{\displaystyle [T,S]^{\prime }=[T^{\prime },S]+[T,S^{\prime }]}](https://wikimedia.org/api/rest_v1/media/math/render/svg/71ac44391b779ac12bcf00ca4a78d14a7c3ebefe)
![{\displaystyle [T,S]=TS-ST}](https://wikimedia.org/api/rest_v1/media/math/render/svg/d03b9d64f949350722fb864bd31c0847d479ff8e)
![{\displaystyle D'=\left({d \over {dx}}\right)'=\operatorname {Id} _{\mathbb {K} [x]}=1.}](https://wikimedia.org/api/rest_v1/media/math/render/svg/067676cf06f192b93b47d2122716b3e8609b6f25)
![{\displaystyle \operatorname {Diff} (\mathbb {K} [x])}](https://wikimedia.org/api/rest_v1/media/math/render/svg/0679517a19bcbe2dfd6753d53a1cc789413af155)
![{\displaystyle [T,S_{h}]=0}](https://wikimedia.org/api/rest_v1/media/math/render/svg/b9d7f519be5767552fbdf4ca92813e07be2a62cc)
![{\displaystyle [T',S_{h}]=0}](https://wikimedia.org/api/rest_v1/media/math/render/svg/3a89c6eddf2fe04808dd7ad0a41bd12c8c6ce21d)
