在泛函分析 和量子信息科學 中,正算子值測度 (Positive operator valued measure, POVM )是一種推廣的測度 ,這種測度的值為希爾伯特空間 上半正定算子 。POVM是投影值測度 (Projection valued measure, PVM ) 的推廣,相應地,POVM描述的量子測量 是PVM描述的量子測量 (稱為投影測量) 的推廣。
粗略比喻來說:POVM之於PVM,就如同混合態 之於純態 一樣。 混合態對於刻畫一個較大系統的子系統的狀態而言是必須的(見量子態的純化 );類似地,POVM的概念則在刻畫在較大系統上進行的投影測量對子系統的影響時自然地產生。
POVM是量子力學中最普遍的測量類型,也用於量子場論 。[1] 量子信息 領域有着廣泛的應用。
定義 設
H
{\displaystyle {\mathcal {H}}}
希爾伯特空間 ,而
(
X
,
M
)
{\displaystyle (X,M)}
可測空間 ,其中
M
{\displaystyle M}
X
{\displaystyle X}
博雷爾σ-代數 。若
M
{\displaystyle M}
F
{\displaystyle F}
H
{\displaystyle {\mathcal {H}}}
正 有界 自伴算子 ,且對於任意
ψ
∈
H
{\displaystyle \psi \in {\mathcal {H}}}
E
∈
M
{\displaystyle E\in M}
E
↦
⟨
F
(
E
)
ψ
|
ψ
⟩
,
{\displaystyle E\mapsto \langle F(E)\psi |\psi \rangle ,}
則
F
{\displaystyle F}
σ-代數
M
{\displaystyle M}
可數可加 測度,且總質量 為恆等算子
F
(
X
)
=
I
H
{\displaystyle F(X)=\operatorname {I} _{\mathcal {H}}}
F
{\displaystyle F}
[2]
在最簡單的情況下,POVM是有限維希爾伯特空間
H
{\displaystyle {\mathcal {H}}}
半正定 埃爾米特矩陣
{
F
i
}
{\displaystyle \{F_{i}\}}
單位矩陣 [3] :90
∑
i
=
1
n
F
i
=
I
.
{\displaystyle \sum _{i=1}^{n}F_{i}=\operatorname {I} .}
POVM與投影值測度 的不同之處在於,對於投影值測量,
F
{\displaystyle F}
正交投影 。
在量子力學 中,POVM的關鍵性質是它確定了結果空間上的一個概率測度,因此
⟨
F
(
E
)
ψ
|
ψ
⟩
{\displaystyle \langle F(E)\psi |\psi \rangle }
量子態
|
ψ
⟩
{\displaystyle |\psi \rangle }
E
{\displaystyle E}
F
i
{\displaystyle F_{i}}
i
{\displaystyle i}
量子態
ρ
{\displaystyle \rho }
量子測量 時得到它的概率
Prob
(
i
)
=
tr
(
ρ
F
i
)
{\displaystyle {\text{Prob}}(i)=\operatorname {tr} (\rho F_{i})}
其中
tr
{\displaystyle \operatorname {tr} }
跡 運算。若被測量的量子態是純態
|
ψ
⟩
{\displaystyle |\psi \rangle }
Prob
(
i
)
=
tr
(
|
ψ
⟩
⟨
ψ
|
F
i
)
=
⟨
ψ
|
F
i
|
ψ
⟩
{\displaystyle {\text{Prob}}(i)=\operatorname {tr} (|\psi \rangle \langle \psi |F_{i})=\langle \psi |F_{i}|\psi \rangle }
POVM的最簡單情況推廣了PVM的最簡單情況,即PVM是一組和為恆等矩陣的正交投影
{
Π
i
}
{\displaystyle \{\Pi _{i}\}}
∑
i
=
1
N
Π
i
=
I
,
Π
i
Π
j
=
δ
i
j
Π
i
.
{\displaystyle \sum _{i=1}^{N}\Pi _{i}=\operatorname {I} ,\quad \Pi _{i}\Pi _{j}=\delta _{ij}\Pi _{i}.}
PVM的概率公式與POVM的概率公式相同。一個重要的區別是POVM的元素不一定正交。因此,POVM元素的數量
n
{\displaystyle n}
N
{\displaystyle N}
奈馬克擴張定理 奈馬克擴張定理 [4] [5] :285
最簡單的情況是,POVM元素作用於一個有限維希爾伯特空間且數目有限。奈馬克擴張定理指出,若
{
F
i
}
i
=
1
n
{\displaystyle \{F_{i}\}_{i=1}^{n}}
d
A
{\displaystyle d_{A}}
H
A
{\displaystyle {\mathcal {H}}_{A}}
d
A
′
{\displaystyle d_{A'}}
H
A
′
{\displaystyle {\mathcal {H}}_{A'}}
{
Π
i
}
i
=
1
n
{\displaystyle \{\Pi _{i}\}_{i=1}^{n}}
等距同構
V
:
H
A
→
H
A
′
{\displaystyle V:{\mathcal {H}}_{A}\to {\mathcal {H}}_{A'}}
i
{\displaystyle i}
F
i
=
V
†
Π
i
V
.
{\displaystyle F_{i}=V^{\dagger }\Pi _{i}V.}
對於秩 為一的POVM的特殊情況,即存在某(未歸一化的)向量
|
f
i
⟩
{\displaystyle |f_{i}\rangle }
F
i
=
|
f
i
⟩
⟨
f
i
|
{\displaystyle F_{i}=|f_{i}\rangle \langle f_{i}|}
[5] :285
V
=
∑
i
=
1
n
|
i
⟩
A
′
⟨
f
i
|
A
{\displaystyle V=\sum _{i=1}^{n}|i\rangle _{A'}\langle f_{i}|_{A}}
而PVM則由
Π
i
=
|
i
⟩
⟨
i
|
A
′
{\displaystyle \Pi _{i}=|i\rangle \langle i|_{A'}}
d
A
′
=
n
{\displaystyle d_{A'}=n}
一般情況下,等距同構和PVM可以通過定義[6] [7]
H
A
′
=
H
A
⊗
H
B
{\displaystyle {\mathcal {H}}_{A'}={\mathcal {H}}_{A}\otimes {\mathcal {H}}_{B}}
Π
i
=
I
A
⊗
|
i
⟩
⟨
i
|
B
{\displaystyle \Pi _{i}=\operatorname {I} _{A}\otimes |i\rangle \langle i|_{B}}
V
=
∑
i
=
1
n
F
i
A
⊗
|
i
⟩
B
{\displaystyle V=\sum _{i=1}^{n}{\sqrt {F_{i}}}_{A}\otimes {|i\rangle }_{B}}
來構造。注意這裏
d
A
′
=
n
d
A
{\displaystyle d_{A'}=nd_{A}}
無論哪種情況,對經過等距映射後的態進行該投影測量得到結果
i
{\displaystyle i}
Prob
(
i
)
=
tr
(
V
ρ
A
V
†
Π
i
)
=
tr
(
ρ
A
V
†
Π
i
V
)
=
tr
(
ρ
A
F
i
)
{\displaystyle {\text{Prob}}(i)=\operatorname {tr} \left(V\rho _{A}V^{\dagger }\Pi _{i}\right)=\operatorname {tr} \left(\rho _{A}V^{\dagger }\Pi _{i}V\right)=\operatorname {tr} (\rho _{A}F_{i})}
通過將該等距同構
V
{\displaystyle V}
擴張 為一個么正算子
U
{\displaystyle U}
U
{\displaystyle U}
∀
1
≤
i
≤
d
A
,
V
|
i
⟩
A
=
U
|
i
⟩
A
′
.
{\displaystyle \forall 1\leq i\leq d_{A},\quad V|i\rangle _{A}=U|i\rangle _{A'}.}
這總是可以做到。
實現對量子態
ρ
{\displaystyle \rho }
{
F
i
}
i
=
1
n
{\displaystyle \{F_{i}\}_{i=1}^{n}}
[需要解釋 ,將
ρ
{\displaystyle \rho }
H
A
′
{\displaystyle {\mathcal {H}}_{A'}}
U
{\displaystyle U}
{
Π
i
}
i
=
1
n
{\displaystyle \{\Pi _{i}\}_{i=1}^{n}}
測量後的狀態 測量後的狀態不是由POVM本身決定的,而是由物理上實現它的PVM來決定。由於相同的POVM有無窮個不同的PVM實現,因此
{
F
i
}
i
=
1
n
{\displaystyle \{F_{i}\}_{i=1}^{n}}
W
{\displaystyle W}
M
i
=
W
F
i
{\displaystyle M_{i}=W{\sqrt {F_{i}}}}
也滿足性質
M
i
†
M
i
=
F
i
{\displaystyle M_{i}^{\dagger }M_{i}=F_{i}}
V
W
=
∑
i
=
1
n
M
i
A
⊗
|
i
⟩
B
{\displaystyle V_{W}=\sum _{i=1}^{n}{M_{i}}_{A}\otimes {|i\rangle }_{B}}
也將實現相同的 POVM。在被測狀態為純態
|
ψ
⟩
A
{\displaystyle |\psi \rangle _{A}}
U
W
{\displaystyle U_{W}}
U
W
(
|
ψ
⟩
A
|
0
⟩
B
)
=
∑
i
=
1
n
M
i
|
ψ
⟩
A
|
i
⟩
B
,
{\displaystyle U_{W}(|\psi \rangle _{A}|0\rangle _{B})=\sum _{i=1}^{n}M_{i}|\psi \rangle _{A}|i\rangle _{B},}
當得到的測量結果為
i
0
{\displaystyle i_{0}}
|
ψ
⟩
A
{\displaystyle |\psi \rangle _{A}}
[3] :84
|
ψ
′
⟩
A
=
M
i
0
|
ψ
⟩
⟨
ψ
|
M
i
0
†
M
i
0
|
ψ
⟩
.
{\displaystyle |\psi '\rangle _{A}={\frac {M_{i_{0}}|\psi \rangle }{\sqrt {\langle \psi |M_{i_{0}}^{\dagger }M_{i_{0}}|\psi \rangle }}}.}
若被測態的密度矩陣為
ρ
A
{\displaystyle \rho _{A}}
ρ
A
′
=
M
i
0
ρ
M
i
0
†
t
r
(
M
i
0
ρ
M
i
0
†
)
.
{\displaystyle \rho '_{A}={M_{i_{0}}\rho M_{i_{0}}^{\dagger } \over {\rm {tr}}(M_{i_{0}}\rho M_{i_{0}}^{\dagger })}.}
因此可見,測量後狀態明確依賴於么正算子
W
{\displaystyle W}
M
i
†
M
i
=
F
i
{\displaystyle M_{i}^{\dagger }M_{i}=F_{i}}
M
i
{\displaystyle M_{i}}
正算子值測量與投影測量的另一個區別在於它通常是不可重複的。若第一次測量得到結果
i
0
{\displaystyle i_{0}}
i
1
{\displaystyle i_{1}}
Prob
(
i
1
|
i
0
)
=
tr
(
M
i
1
M
i
0
ρ
M
i
0
†
M
i
1
†
)
t
r
(
M
i
0
ρ
M
i
0
†
)
{\displaystyle {\text{Prob}}(i_{1}|i_{0})={\operatorname {tr} (M_{i_{1}}M_{i_{0}}\rho M_{i_{0}}^{\dagger }M_{i_{1}}^{\dagger }) \over {\rm {tr}}(M_{i_{0}}\rho M_{i_{0}}^{\dagger })}}
它在
M
i
0
{\displaystyle M_{i_{0}}}
M
i
1
{\displaystyle M_{i_{1}}}
一個例子:無歧義量子態分辨 態的布洛赫球 表示(藍色)與對態
|
ψ
⟩
=
|
0
⟩
{\displaystyle |\psi \rangle =|0\rangle }
|
φ
⟩
=
1
2
(
|
0
⟩
+
|
1
⟩
)
{\displaystyle |\varphi \rangle ={\frac {1}{\sqrt {2}}}(|0\rangle +|1\rangle )}
假定有一量子系統對應的希爾伯特空間為二維的,其態要麼是
|
ψ
⟩
{\displaystyle |\psi \rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
|
ψ
⟩
{\displaystyle |\psi \rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
{
|
ψ
⟩
⟨
ψ
|
,
|
φ
⟩
⟨
φ
|
}
{\displaystyle \{|\psi \rangle \langle \psi |,|\varphi \rangle \langle \varphi |\}}
|
ψ
⟩
{\displaystyle |\psi \rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
[3] :87 完美辨認非正交態的不可實現性是各種量子信息協議(如量子密碼學 、量子硬幣翻轉 量子貨幣 )的基礎。
退而求其次,實際能做到的最好效果是所謂無歧義量子態分辨(Unambigious quantum state discrimination, UQSD):在系統處於
|
ψ
⟩
{\displaystyle |\psi \rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
[8]
|
ψ
⊥
⟩
{\displaystyle |\psi ^{\perp }\rangle }
|
ψ
⟩
{\displaystyle |\psi \rangle }
{
|
ψ
⟩
⟨
ψ
|
,
|
ψ
⊥
⟩
⟨
ψ
⊥
|
}
{\displaystyle \{|\psi \rangle \langle \psi |,|\psi ^{\perp }\rangle \langle \psi ^{\perp }|\}}
|
ψ
⊥
⟩
⟨
ψ
⊥
|
{\displaystyle |\psi ^{\perp }\rangle \langle \psi ^{\perp }|}
|
φ
⟩
{\displaystyle |\varphi \rangle }
|
ψ
⟩
⟨
ψ
|
{\displaystyle |\psi \rangle \langle \psi |}
{
|
φ
⟩
⟨
φ
|
,
|
φ
⊥
⟩
⟨
φ
⊥
|
}
{\displaystyle \{|\varphi \rangle \langle \varphi |,|\varphi ^{\perp }\rangle \langle \varphi ^{\perp }|\}}
|
φ
⊥
⟩
{\displaystyle |\varphi ^{\perp }\rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
然而這並不足以令人滿意,這種方法無法用單一測量來探測
|
ψ
⟩
{\displaystyle |\psi \rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
[8] [9]
F
ψ
=
1
1
+
|
⟨
φ
|
ψ
⟩
|
|
φ
⊥
⟩
⟨
φ
⊥
|
{\displaystyle F_{\psi }={\frac {1}{1+|\langle \varphi |\psi \rangle |}}|\varphi ^{\perp }\rangle \langle \varphi ^{\perp }|}
F
φ
=
1
1
+
|
⟨
φ
|
ψ
⟩
|
|
ψ
⊥
⟩
⟨
ψ
⊥
|
{\displaystyle F_{\varphi }={\frac {1}{1+|\langle \varphi |\psi \rangle |}}|\psi ^{\perp }\rangle \langle \psi ^{\perp }|}
F
?
=
I
−
F
ψ
−
F
φ
=
2
|
⟨
φ
|
ψ
⟩
|
1
+
|
⟨
φ
|
ψ
⟩
|
|
γ
⟩
⟨
γ
|
,
{\displaystyle F_{?}=\operatorname {I} -F_{\psi }-F_{\varphi }={\frac {2|\langle \varphi |\psi \rangle |}{1+|\langle \varphi |\psi \rangle |}}|\gamma \rangle \langle \gamma |,}
其中
|
γ
⟩
=
1
2
(
1
+
|
⟨
φ
|
ψ
⟩
|
)
(
|
ψ
⟩
+
e
i
arg
(
⟨
φ
|
ψ
⟩
)
|
φ
⟩
)
.
{\displaystyle |\gamma \rangle ={\frac {1}{\sqrt {2(1+|\langle \varphi |\psi \rangle |)}}}(|\psi \rangle +e^{i\arg(\langle \varphi |\psi \rangle )}|\varphi \rangle ).}
注意到
tr
(
|
φ
⟩
⟨
φ
|
F
ψ
)
=
tr
(
|
ψ
⟩
⟨
ψ
|
F
φ
)
=
0
{\displaystyle \operatorname {tr} (|\varphi \rangle \langle \varphi |F_{\psi })=\operatorname {tr} (|\psi \rangle \langle \psi |F_{\varphi })=0}
ψ
{\displaystyle \psi }
|
ψ
⟩
{\displaystyle |\psi \rangle }
φ
{\displaystyle \varphi }
|
φ
⟩
{\displaystyle |\varphi \rangle }
當系統處於
|
ψ
⟩
{\displaystyle |\psi \rangle }
|
φ
⟩
{\displaystyle |\varphi \rangle }
1
−
|
⟨
φ
|
ψ
⟩
|
.
{\displaystyle 1-|\langle \varphi |\psi \rangle |.}
這一結果稱為 Ivanović-Dieks-Peres 極限,冠名於UQSD研究的先驅者.[10] [11] [12]
由於這些POVM是秩為一的,可以看到通過前文敘述的構造投影測量的方法,便可在物理上實現這些POVM。將擴大後的希爾伯特空間中的三種可能的態分別標記為
|
result ψ
⟩
{\displaystyle |{\text{result ψ}}\rangle }
|
result φ
⟩
{\displaystyle |{\text{result φ}}\rangle }
|
result ?
⟩
{\displaystyle |{\text{result ?}}\rangle }
U
UQSD
{\displaystyle U_{\text{UQSD}}}
|
ψ
⟩
{\displaystyle |\psi \rangle }
U
UQSD
|
ψ
⟩
=
1
−
|
⟨
φ
|
ψ
⟩
|
|
result ψ
⟩
+
|
⟨
φ
|
ψ
⟩
|
|
result ?
⟩
,
{\displaystyle U_{\text{UQSD}}|\psi \rangle ={\sqrt {1-|\langle \varphi |\psi \rangle |}}|{\text{result ψ}}\rangle +{\sqrt {|\langle \varphi |\psi \rangle |}}|{\text{result ?}}\rangle ,}
類似地,它在
|
φ
⟩
{\displaystyle |\varphi \rangle }
U
UQSD
|
φ
⟩
=
1
−
|
⟨
φ
|
ψ
⟩
|
|
result φ
⟩
+
e
−
i
arg
(
⟨
φ
|
ψ
⟩
)
|
⟨
φ
|
ψ
⟩
|
|
result ?
⟩
.
{\displaystyle U_{\text{UQSD}}|\varphi \rangle ={\sqrt {1-|\langle \varphi |\psi \rangle |}}|{\text{result φ}}\rangle +e^{-i\arg(\langle \varphi |\psi \rangle )}{\sqrt {|\langle \varphi |\psi \rangle |}}|{\text{result ?}}\rangle .}
於是投影測量便可以相同於POVM的概率來得到所要的結果。
這種POVM已在實驗上用於區分一個光子的非正交偏振態。不過實現該POVM的投影測量與此處闡述的有輕微的不同。[13] [14]
參見 參考資料
^ Peres, Asher ; Terno, Daniel R. Quantum information and relativity theory. Reviews of Modern Physics . 2004, 76 (1): 93–123. Bibcode:2004RvMP...76...93P S2CID 7481797 arXiv:quant-ph/0212023 doi:10.1103/RevModPhys.76.93 ^ Davies, Edward Brian. Quantum Theory of Open Systems. London: Acad. Press. 1976: 35. ISBN 978-0-12-206150-9 ^ 3.0 3.1 3.2 M. Nielsen and I. Chuang, Quantum Computation and Quantum Information, Cambridge University Press, (2000)
^ I. M. Gelfand and M. A. Neumark, On the embedding of normed rings into the ring of operators in Hilbert space, Rec. Math. [Mat. Sbornik] N.S. 12(54) (1943), 197–213.
^ 5.0 5.1 A. Peres. Quantum Theory: Concepts and Methods. Kluwer Academic Publishers, 1993.
^ J. Preskill, Lecture Notes for Physics: Quantum Information and Computation, Chapter 3, http://theory.caltech.edu/~preskill/ph229/index.html
^ J. Watrous. The Theory of Quantum Information. Cambridge University Press, 2018. Chapter 2.3, https://cs.uwaterloo.ca/~watrous/TQI/
^ 8.0 8.1 J.A. Bergou; U. Herzog; M. Hillery. Discrimination of Quantum States. M. Paris; J. Řeháček (編). Quantum State Estimation 417 –465. ISBN 978-3-540-44481-7doi:10.1007/978-3-540-44481-7_11 ^ Chefles, Anthony. Quantum state discrimination. Contemporary Physics (Informa UK Limited). 2000, 41 (6): 401–424. Bibcode:2000ConPh..41..401C ISSN 0010-7514 S2CID 119340381 arXiv:quant-ph/0010114v1 doi:10.1080/00107510010002599 ^ Ivanovic, I.D. How to differentiate between non-orthogonal states. Physics Letters A (Elsevier BV). 1987, 123 (6): 257–259. Bibcode:1987PhLA..123..257I ISSN 0375-9601 doi:10.1016/0375-9601(87)90222-2 ^ Dieks, D. Overlap and distinguishability of quantum states. Physics Letters A (Elsevier BV). 1988, 126 (5–6): 303–306. Bibcode:1988PhLA..126..303D ISSN 0375-9601 doi:10.1016/0375-9601(88)90840-7 ^ Peres, Asher. How to differentiate between non-orthogonal states. Physics Letters A (Elsevier BV). 1988, 128 (1–2): 19. Bibcode:1988PhLA..128...19P ISSN 0375-9601 doi:10.1016/0375-9601(88)91034-1 ^ B. Huttner; A. Muller; J. D. Gautier; H. Zbinden; N. Gisin. Unambiguous quantum measurement of nonorthogonal states. Physical Review A (APS). 1996, 54 (5): 3783–3789. Bibcode:1996PhRvA..54.3783H PMID 9913923 doi:10.1103/PhysRevA.54.3783 ^ R. B. M. Clarke; A. Chefles; S. M. Barnett; E. Riis. Experimental demonstration of optimal unambiguous state discrimination. Physical Review A (APS). 2001, 63 (4): 040305(R). Bibcode:2001PhRvA..63d0305C S2CID 39481893 arXiv:quant-ph/0007063 doi:10.1103/PhysRevA.63.040305
外部連結 
. doi:10.1103/RevModPhys.76.93.
. Springer. 2004: 417–465. ISBN 978-3-540-44481-7. doi:10.1007/978-3-540-44481-7_11.
