In mathematics, the Fubini–Study metric (IPA: /fubini-ʃtuːdi/) is a Kähler metric on a complex projective space CPn endowed with a Hermitian form. This metric was originally described in 1904 and 1905 by Guido Fubini and Eduard Study.[1] [2]
A Hermitian form in (the vector space) Cn+1 defines a unitary subgroup U(n+1) in GL(n+1,C). A Fubini–Study metric is determined up to homothety (overall scaling) by invariance under such a U(n+1) action; thus it is homogeneous. Equipped with a Fubini–Study metric, CPn is a symmetric space. The particular normalization on the metric depends on the application. In Riemannian geometry, one uses a normalization so that the Fubini–Study metric simply relates to the standard metric on the (2n+1)-sphere. In algebraic geometry, one uses a normalization making CPn a Hodge manifold.
The Fubini–Study metric arises naturally in the quotient space construction of complex projective space.
Specifically, one may define CPn to be the space consisting of all complex lines in Cn+1, i.e., the quotient of Cn+1\ by the equivalence relation relating all complex multiples of each point together. This agrees with the quotient by the diagonal group action of the multiplicative group C* = C \ :
CPn=\left\{Z=[Z0,Z1,\ldots,Zn]\in{C}n+1\setminus\{0\}\right\}/\{Z\simcZ,c\inC*\}.
This quotient realizes Cn+1\ as a complex line bundle over the base space CPn. (In fact this is the so-called tautological bundle over CPn.) A point of CPn is thus identified with an equivalence class of (n+1)-tuples [''Z''<sub>0</sub>,...,''Z''<sub>''n''</sub>] modulo nonzero complex rescaling; the Zi are called homogeneous coordinates of the point.
Furthermore, one may realize this quotient mapping in two steps: since multiplication by a nonzero complex scalar z = R eiθ can be uniquely thought of as the composition of a dilation by the modulus R followed by a counterclockwise rotation about the origin by an angle
\theta
Cn+1\setminus\{0\}l{\stackrel{(a)}\longrightarrow}S2n+1l{\stackrel{(b)}\longrightarrow}CPn
where step (a) is a quotient by the dilation Z ~ RZ for R ∈ R+, the multiplicative group of positive real numbers, and step (b) is a quotient by the rotations Z ~ eiθZ.
The result of the quotient in (a) is the real hypersphere S2n+1 defined by the equation |Z|2 = |Z0|2 + ... + |Zn|2 = 1. The quotient in (b) realizes CPn = S2n+1/S1, where S1 represents the group of rotations. This quotient is realized explicitly by the famous Hopf fibration S1 → S2n+1 → CPn, the fibers of which are among the great circles of
S2n+1
When a quotient is taken of a Riemannian manifold (or metric space in general), care must be taken to ensure that the quotient space is endowed with a metric that is well-defined. For instance, if a group G acts on a Riemannian manifold (X,g), then in order for the orbit space X/G to possess an induced metric,
g
X,Y
The standard Hermitian metric on Cn+1 is given in the standard basis by
ds2=dZ ⊗ d\bar{Z
whose realification is the standard Euclidean metric on R2n+2. This metric is not invariant under the diagonal action of C*, so we are unable to directly push it down to CPn in the quotient. However, this metric is invariant under the diagonal action of S1 = U(1), the group of rotations. Therefore, step (b) in the above construction is possible once step (a) is accomplished.
The Fubini–Study metric is the metric induced on the quotient CPn = S2n+1/S1, where
S2n+1
Corresponding to a point in CPn with homogeneous coordinates
[Z0:...:Zn]
(z1,...,zn)
[Z0:...:Zn]\sim[1,z1,...,zn],
Z0 ≠ 0
zj=Zj/Z0
(z1,...,zn)
U0=\{Z0 ≠ 0\}
Ui=\{Zi ≠ 0\}
Zi
Ui
(z1,...,zn)
Ui
\{\partial1,\ldots,\partialn\}
gi\bar{j
where |z|2 = |z1|2 + ... + |zn|2. That is, the Hermitian matrix of the Fubini–Study metric in this frame is
l[gi\bar{j
Note that each matrix element is unitary-invariant: the diagonal action
z\mapstoei\thetaz
Accordingly, the line element is given by
\begin{align} ds2&=gi\bar{j
The metric can be derived from the following Kähler potential:[3]
K=ln(1+zi\bar{z}i)=ln(1+\deltai\bar{j
gi\bar{j
An expression is also possible in the notation of homogeneous coordinates, commonly used to describe projective varieties of algebraic geometry: Z = [''Z''<sub>0</sub>:...:''Z''<sub>''n''</sub>]. Formally, subject to suitably interpreting the expressions involved, one has
\begin{align} ds2&=
| |Z|2|dZ|2-(\bar{Z | |
| ⋅ |
dZ)(Z ⋅ d\bar{Z
| ^4 |
Here the summation convention is used to sum over Greek indices α β ranging from 0 to n, and in the last equality the standard notation for the skew part of a tensor is used:
Z[\alphaW\beta]=\tfrac12\left(Z\alphaW\beta-Z\betaW\alpha\right).
Now, this expression for ds2 apparently defines a tensor on the total space of the tautological bundle Cn+1\. It is to be understood properly as a tensor on CPn by pulling it back along a holomorphic section σ of the tautological bundle of CPn. It remains then to verify that the value of the pullback is independent of the choice of section: this can be done by a direct calculation.
The Kähler form of this metric is
\omega=
| i | |
| 2 |
\partial\bar{\partial}log|Z|2
where the
\partial,\bar\partial
In quantum mechanics, the Fubini–Study metric is also known as the Bures metric.[4] However, the Bures metric is typically defined in the notation of mixed states, whereas the exposition below is written in terms of a pure state. The real part of the metric is (a quarter of) the Fisher information metric.[4]
The Fubini–Study metric may be written using the bra–ket notation commonly used in quantum mechanics. To explicitly equate this notation to the homogeneous coordinates given above, let
\vert\psi\rangle=
| n | |
| \sum | |
| k=0 |
Zk\vertek\rangle=[Z0:Z1:\ldots:Zn]
where
\{\vertek\rangle\}
Zk
Z\alpha=[Z0:Z1:\ldots:Zn]
\vert\psi\rangle=Z\alpha
\vert\varphi\rangle=W\alpha
\gamma(\psi,\varphi)=\arccos\sqrt
| \langle\psi\vert\varphi\rangle \langle\varphi\vert\psi\rangle | |
| \langle\psi\vert\psi\rangle \langle\varphi\vert\varphi\rangle |
\gamma(\psi,\varphi)=\gamma(Z,W)=\arccos\sqrt{
| Z\alpha\bar{W | |
| \alpha |
W\beta
| \beta} {Z | |
| \bar{Z} | |
| \alpha |
\bar{Z}\alpha W\beta\bar{W}\beta}}.
Here,
\bar{Z}\alpha
Z\alpha
\langle\psi\vert\psi\rangle
\vert\psi\rangle
\vert\varphi\rangle
\pi/2
The infinitesimal form of this metric may be quickly obtained by taking
\varphi=\psi+\delta\psi
W\alpha=Z\alpha+dZ\alpha
ds2=
| \langle\delta\psi\vert\delta\psi\rangle | |
| \langle\psi\vert\psi\rangle |
-
| \langle\delta\psi\vert\psi\rangle \langle\psi\vert\delta\psi\rangle | |
| {\langle\psi\vert\psi\rangle |
2}.
In the context of quantum mechanics, CP1 is called the Bloch sphere; the Fubini–Study metric is the natural metric for the geometrization of quantum mechanics. Much of the peculiar behaviour of quantum mechanics, including quantum entanglement and the Berry phase effect, can be attributed to the peculiarities of the Fubini–Study metric.
When n = 1, there is a diffeomorphism
S2\congCP1
Namely, if z = x + iy is the standard affine coordinate chart on the Riemann sphere CP1 and x = r cos θ, y = r sin θ are polar coordinates on C, then a routine computation shows
ds2=
| \operatorname{Re | |
| (dz |
⊗ d\bar{z})}{\left(1+|z|\vphantom{l}2\right)2} =
| dx2+dy2 | |
| \left(1+r2\right)2 |
=\tfrac14(d\varphi2+\sin2\varphid\theta2) =\tfrac14
| 2 | |
| ds | |
| us |
where
| 2 | |
| ds | |
| us |
The Kähler form is
| K= | i |
| 2 |
| dz\wedged\bar{z | |
Choosing as vierbeins
e1=dx/(1+r2)
e2=dy/(1+r2)
K=e1\wedgee2
*K=1
The Fubini–Study metric on the complex projective plane CP2 has been proposed as a gravitational instanton, the gravitational analog of an instanton.[5] [3] The metric, the connection form and the curvature are readily computed, once suitable real 4D coordinates are established. Writing
(x,y,z,t)
\begin{align} rdr&=+xdx+ydy+zdz+tdt
| 2\sigma | |
| \\ r | |
| 1 |
&=-tdx-zdy+ydz+xdt
| 2\sigma | |
| \\ r | |
| 2 |
&=+zdx-tdy-xdz+ydt
| 2\sigma | |
| \\ r | |
| 3 |
&=-ydx+xdy-tdz+zdt \end{align}
\sigma1,\sigma2,\sigma3
SU(2)=S3
d\sigmai=2\sigmaj\wedge\sigmak
i,j,k=1,2,3
The corresponding local affine coordinates are
z1=x+iy
z2=z+it
\begin{align} z1\bar{z}1+z2\bar{z}2&=r2=x2+y2+z2+t2\\ dz1d\bar{z}1+dz2d\bar{z}2&=dr2+
| 2 | |
| r | |
| 1 |
| 2 | |
| +\sigma | |
| 2 |
| 2 | |
| +\sigma | |
| 3 |
)\\ \bar{z}1dz1+\bar{z}2dz2&=rdr+ir2\sigma3\end{align}
dr2=dr ⊗ dr
| 2 | |
| \sigma | |
| k |
=\sigmak ⊗ \sigmak
The line element, starting with the previously given expression, is given by
\begin{align} ds2&=
| dzjd\bar{z | |
| j}{1+z |
| i} | |
| i\bar{z} |
-
| \bar{z | |
| j |
zidz
| i) | |
| i\bar{z} |
2}\\[5pt] &=
| |||||||||||||||||||||||||
| 1+r2 |
-
| |||||||||||||
| \left(1+r2\right)2 |
\\[4pt] &=
| |||||||||||||
| \left(1+r2\right)2 |
+
| ||||||||||||||||
| 1+r2 |
\end{align}
The vierbeins can be immediately read off from the last expression:
\begin{align} e0=
| dr | |
| 1+r2 |
&&& e3=
| r\sigma3 | |
| 1+r2 |
\\[5pt] e1=
| r\sigma1 | |
| \sqrt{1+r2 |
That is, in the vierbein coordinate system, using roman-letter subscripts, the metric tensor is Euclidean:
| 2=\delta | |
| ds | |
| ab |
ea ⊗ eb=e0 ⊗ e0+e1 ⊗ e1+e2 ⊗ e2+e3 ⊗ e3.
Given the vierbein, a spin connection can be computed; the Levi-Civita spin connection is the unique connection that is torsion-free and covariantly constant, namely, it is the one-form
| a | |
| \omega | |
| b |
dea+
| a | |
| \omega | |
| b |
\wedgeeb=0
\omegaab=-\omegaba
The above is readily solved; one obtains
| 0 | |
| \begin{align} \omega | |
| 1 |
&=-
| 2 | |
| \omega | |
| 3 |
=-
| e1 | |
| r |
| 0 | |
| \\ \omega | |
| 2 |
&=-
| 3 | |
| \omega | |
| 1 |
=-
| e2 | |
| r |
| 0 | |
| \\ \omega | |
| 3 |
&=
| r2-1 | |
| r |
e3
| 1 | |
| \omega | |
| 2 |
=
| 1+2r2 | |
| r |
e3\\ \end{align}
The curvature 2-form is defined as
| a | |
| R | |
| b |
=
| a | |
| d\omega | |
| b |
+
| a | |
| \omega | |
| c |
\wedge
| c | |
| \omega | |
| b |
\begin{align} R01&=-R23=e0\wedgee1-e2\wedgee3\\ R02&=-R31=e0\wedgee2-e3\wedgee1\\ R03&=4e0\wedgee3+2e1\wedgee2\\ R12&=2e0\wedgee3+4e1\wedgee2 \end{align}
The Ricci tensor in veirbein indexes is given by
| a | |
| \operatorname{Ric} | |
| c |
| a | |
| =R | |
| bcd |
\deltabd
where the curvature 2-form was expanded as a four-component tensor:
| a | |
| R | |
| b |
=\tfrac12
| a | |
| R | |
| bcd |
ec\wedgeed
The resulting Ricci tensor is constant
\operatorname{Ric}ab-\tfrac12\deltaabR+Λ\deltaab=0
Λ=6
The Weyl tensor for Fubini–Study metrics in general is given by
Wabcd=Rabcd-2\left(\deltaac\deltabd-\deltaad\deltabc\right)
Wab=\tfrac12Wabcdec\wedgeed
\begin{align} W01&=W23=-e0\wedgee1-e2\wedgee3\\ W02&=W31=-e0\wedgee2-e3\wedgee1\\ W03&=W12=2e0\wedgee3+2e1\wedgee2 \end{align}
In the n = 1 special case, the Fubini–Study metric has constant sectional curvature identically equal to 4, according to the equivalence with the 2-sphere's round metric (which given a radius R has sectional curvature
1/R2
K(\sigma)=1+3\langleJX,Y\rangle2
where
\{X,Y\}\inTpCPn
\langle ⋅ , ⋅ \rangle
A consequence of this formula is that the sectional curvature satisfies
1\leqK(\sigma)\leq4
\sigma
This makes CPn a (non-strict) quarter pinched manifold; a celebrated theorem shows that a strictly quarter-pinched simply connected n-manifold must be homeomorphic to a sphere.
The Fubini–Study metric is also an Einstein metric in that it is proportional to its own Ricci tensor: there exists a constant
Λ
\operatorname{Ric}ij=Λgij.
This implies, among other things, that the Fubini–Study metric remains unchanged up to a scalar multiple under the Ricci flow. It also makes CPn indispensable to the theory of general relativity, where it serves as a nontrivial solution to the vacuum Einstein field equations.
Λ
\operatorname{Ric}ij=2(n+1)gij.
The common notions of separability apply for the Fubini–Study metric. More precisely, the metric is separable on the natural product of projective spaces, the Segre embedding. That is, if
\vert\psi\rangle
\vert\psi\rangle=\vert\psiA\rangle ⊗ \vert\psiB\rangle
ds2=
| 2 | |
| {ds | |
| B} |
where
| 2 | |
| {ds | |
| A} |
| 2 | |
| {ds | |
| B} |
The fact that the metric can be derived from the Kähler potential means that the Christoffel symbols and the curvature tensors contain a lot of symmetries, and can be given a particularly simple form:[7] The Christoffel symbols, in the local affine coordinates, are given by
| i | |
| \Gamma | |
| jk |
=gi\bar{m
Ri\bar{jk\bar{l}}=gi\bar{m
R\bar{ij}=R\bar{k