Local system

In mathematics, a local system (or a system of local coefficients) on a topological space X is a tool from algebraic topology which interpolates between cohomology with coefficients in a fixed abelian group A, and general sheaf cohomology in which coefficients vary from point to point. Local coefficient systems were introduced by Norman Steenrod in 1943.^[1]

Local systems are the building blocks of more general tools, such as constructible and perverse sheaves.

Let X be a topological space. A local system (of abelian groups/modules/...) on X is a locally constant sheaf (of abelian groups/modules...) on X. In other words, a sheaf ${\displaystyle {ℒ}}$ is a local system if every point has an open neighborhood ${\displaystyle U}$ such that the restricted sheaf ${\displaystyle {ℒ}{|}_U}$ is isomorphic to the sheafification of some constant presheaf. ^{[clarification needed]}

If X is path-connected,^{[clarification needed]} a local system ${\displaystyle {ℒ}}$ of abelian groups has the same stalk L at every point. There is a bijective correspondence between local systems on X and group homomorphisms

${\displaystyle \rho :{\pi }_1(X,x)\to \text{Aut}(L)}$

and similarly for local systems of modules. The map ${\displaystyle {\pi }_1(X,x)\to \text{End}(L)}$ giving the local system ${\displaystyle {ℒ}}$ is called the monodromy representation of ${\displaystyle {ℒ}}$.

This shows that (for X path-connected) a local system is precisely a sheaf whose pullback to the universal cover of X is a constant sheaf.

This correspondence can be upgraded to an equivalence of categories between the category of local systems of abelian groups on X and the category of abelian groups endowed with an action of ${\displaystyle {\pi }_1(X,x)}$ (equivalently, ${\displaystyle \mathbb{\mathbb{Z}}[{\pi }_1(X,x)]}$-modules).^[2]

A stronger nonequivalent definition that works for non-connected X is: the following: a local system is a covariant functor

${\displaystyle {ℒ}:{\mathrm{\Pi }}_1(X)\to \text{<mrow data-mjx-texclass="ORD">Mod</mrow>}(R)}$

from the fundamental groupoid of ${\displaystyle X}$ to the category of modules over a commutative ring ${\displaystyle R}$, where typically ${\displaystyle R=\mathbb{\mathbb{Q}},\mathbb{ℝ},\mathbb{ℂ}}$. This is equivalently the data of an assignment to every point ${\displaystyle x\in X}$ a module ${\displaystyle M}$ along with a group representation ${\displaystyle {\rho }_x:{\pi }_1(X,x)\to {\text{Aut}}_R(M)}$ such that the various ${\displaystyle {\rho }_x}$ are compatible with change of basepoint ${\displaystyle x\to y}$ and the induced map ${\displaystyle {\pi }_1(X,x)\to {\pi }_1(X,y)}$ on fundamental groups.

• Constant sheaves such as ${\displaystyle {\underset{\_}{\mathbb{\mathbb{Q}}}}_X}$. This is a useful tool for computing cohomology since in good situations, there is an isomorphism between sheaf cohomology and singular cohomology:

$${\displaystyle H^k(X,{\underset{\_}{\mathbb{\mathbb{Q}}}}_X)\cong H_{\text{sing}}^k(X,\mathbb{\mathbb{Q}})}$$

• Let ${\displaystyle X={\mathbb{ℝ}}^2\setminus \{(0,0)\}}$. Since ${\displaystyle {\pi }_1({\mathbb{ℝ}}^2\setminus \{(0,0)\})=\mathbb{\mathbb{Z}}}$, there is an ${\displaystyle S^1}$ family of local systems on X corresponding to the maps ${\displaystyle n\mapsto e^{in\theta }}$:

$${\displaystyle {\rho }_{\theta }:{\pi }_1(X;x_0)\cong \mathbb{\mathbb{Z}}\to {\text{Aut}}_{\mathbb{ℂ}}(\mathbb{ℂ})}$$

• Horizontal sections of vector bundles with a flat connection. If ${\displaystyle E\to X}$ is a vector bundle with flat connection ${\displaystyle \mathrm{\nabla }}$, then there is a local system given by $${\displaystyle E_U^{\mathrm{\nabla }}=\{\text{sections }s\in \mathrm{\Gamma }(U,E)\text{ which are horizontal: }\mathrm{\nabla }s=0\}}$$ For instance, take ${\displaystyle X=\mathbb{ℂ}\setminus 0}$ and ${\displaystyle E=X\times \mathbb{ℂ}{.}^n}$ the trivial bundle. Sections of E are n-tuples of functions on X, so ${\displaystyle {\mathrm{\nabla }}_0(f_1,\dots ,f_n)=(d{f}_1,\dots ,d{f}_n)}$ defines a flat connection on E, as does ${\displaystyle \mathrm{\nabla }(f_1,\dots ,f_n)=(d{f}_1,\dots ,d{f}_n)-\mathrm{\Theta }(x)(f_1,\dots ,f_n{)}^t}$ for any matrix of one-forms ${\displaystyle \mathrm{\Theta }}$ on X. The horizontal sections are then
  $${\displaystyle E_U^{\mathrm{\nabla }}=\{(f_1,\dots ,f_n)\in E_U:(d{f}_1,\dots ,d{f}_n)=\mathrm{\Theta }(f_1,\dots ,f_n{)}^t\}}$$ i.e., the solutions to the linear differential equation ${\displaystyle d{f}_i=\sum {\mathrm{\Theta }}_{ij}{f}_j}$.

  If ${\displaystyle \mathrm{\Theta }}$ extends to a one-form on ${\displaystyle \mathbb{ℂ}}$ the above will also define a local system on ${\displaystyle \mathbb{ℂ}}$, so will be trivial since ${\displaystyle {\pi }_1(\mathbb{ℂ})=0}$. So to give an interesting example, choose one with a pole at 0:

  $${\displaystyle \mathrm{\Theta }=\left(\begin{array}{cc}0& dx/x\\ dx& e^{x}dx\end{array}\right)}$$ in which case for ${\displaystyle \mathrm{\nabla }=d+\mathrm{\Theta }}$, $${\displaystyle E_U^{\mathrm{\nabla }}=\{f_1,f_2:U\to \mathbb{ℂ}\text{ with }f{\text{'}}_1=f_2/x{f_2}^{\prime }=f_1+e^x{f}_2\}}$$

• An n-sheeted covering map ${\displaystyle X\to Y}$ is a local system with fibers given by the set ${\displaystyle \{1,\dots ,n\}}$. Similarly, a fibre bundle with discrete fibre is a local system, because each path lifts uniquely to a given lift of its basepoint. (The definition adjusts to include set-valued local systems in the obvious way).

• A local system of k-vector spaces on X is equivalent to a k-linear representation of ${\displaystyle {\pi }_1(X,x)}$.

• If X is a variety, local systems are the same thing as D-modules which are additionally coherent O_X-modules (see O modules).

• If the connection is not flat (i.e. its curvature is nonzero), then parallel transport of a fibre F_x over x around a contractible loop based at x_0 may give a nontrivial automorphism of F_x, so locally constant sheaves can not necessarily be defined for non-flat connections.

• The Gauss–Manin connection is a prominent example of a connection whose horizontal sections are studied in relation to variation of Hodge structures.

There are several ways to define the cohomology of a local system, called cohomology with local coefficients, which become equivalent under mild assumptions on X.

• Given a locally constant sheaf ${\displaystyle {ℒ}}$ of abelian groups on X, we have the sheaf cohomology groups ${\displaystyle H^j(X,{ℒ})}$ with coefficients in ${\displaystyle {ℒ}}$.

• Given a locally constant sheaf ${\displaystyle {ℒ}}$ of abelian groups on X, let ${\displaystyle C^n(X;{ℒ})}$ be the group of all functions f which map each singular n-simplex ${\displaystyle \sigma :{\mathrm{\Delta }}^n\to X}$ to a global section ${\displaystyle f(\sigma )}$ of the inverse-image sheaf ${\displaystyle {\sigma }^{-1}{ℒ}}$. These groups can be made into a cochain complex with differentials constructed as in usual singular cohomology. Define ${\displaystyle H_{\mathrm{s}\mathrm{i}\mathrm{n}\mathrm{g}}^j(X;{ℒ})}$ to be the cohomology of this complex.

• The group ${\displaystyle C_n(\tilde{X})}$ of singular n-chains on the universal cover of X has an action of ${\displaystyle {\pi }_1(X,x)}$ by deck transformations. Explicitly, a deck transformation ${\displaystyle \gamma :\tilde{X}\to \tilde{X}}$ takes a singular n-simplex ${\displaystyle \sigma :{\mathrm{\Delta }}^n\to \tilde{X}}$ to ${\displaystyle \gamma \circ \sigma }$. Then, given an abelian group L equipped with an action of ${\displaystyle {\pi }_1(X,x)}$, one can form a cochain complex from the groups ${\displaystyle {\mathrm{Hom}}_{{\pi }_1(X,x)}(C_n(\tilde{X}),L)}$ of ${\displaystyle {\pi }_1(X,x)}$-equivariant homomorphisms as above. Define ${\displaystyle H_{\mathrm{s}\mathrm{i}\mathrm{n}\mathrm{g}}^j(X;L)}$ to be the cohomology of this complex.

If X is paracompact and locally contractible, then ${\displaystyle H^j(X,{ℒ})\cong H_{\mathrm{s}\mathrm{i}\mathrm{n}\mathrm{g}}^j(X;{ℒ})}$.^[3] If ${\displaystyle {ℒ}}$ is the local system corresponding to L, then there is an identification ${\displaystyle C^n(X;{ℒ})\cong {\mathrm{Hom}}_{{\pi }_1(X,x)}(C_n(\tilde{X}),L)}$ compatible with the differentials,^[4] so ${\displaystyle H_{\mathrm{s}\mathrm{i}\mathrm{n}\mathrm{g}}^j(X;{ℒ})\cong H_{\mathrm{s}\mathrm{i}\mathrm{n}\mathrm{g}}^j(X;L)}$.

Local systems have a mild generalization to constructible sheaves -- a constructible sheaf on a locally path connected topological space ${\displaystyle X}$ is a sheaf ${\displaystyle {ℒ}}$ such that there exists a stratification of

${\displaystyle X=\coprod X_{\lambda }}$

where ${\displaystyle {ℒ}{|}_{X_{\lambda }}}$ is a local system. These are typically found by taking the cohomology of the derived pushforward for some continuous map ${\displaystyle f:X\to Y}$. For example, if we look at the complex points of the morphism

${\displaystyle f:X=\text{Proj}\left(\frac{\mathbb{ℂ}[s,t][x,y,z]}{(stf(x,y,z))}\right)\to \text{Spec}(\mathbb{ℂ}[s,t])}$

then the fibers over

${\displaystyle {\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}$

are the smooth plane curve given by ${\displaystyle f}$, but the fibers over ${\displaystyle \mathbb{𝕍}}$ are ${\displaystyle {\mathbb{\mathbb{P}}}^2}$. If we take the derived pushforward ${\displaystyle \mathbf{𝐑}{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X)}$ then we get a constructible sheaf. Over ${\displaystyle \mathbb{𝕍}}$ we have the local systems

${\displaystyle \begin{array}{rl}{\mathbf{𝐑}}^0{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{\mathbb{𝕍}(st)}& ={\underset{\_}{\mathbb{\mathbb{Q}}}}_{\mathbb{𝕍}(st)}\\ {\mathbf{𝐑}}^2{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{\mathbb{𝕍}(st)}& ={\underset{\_}{\mathbb{\mathbb{Q}}}}_{\mathbb{𝕍}(st)}\\ {\mathbf{𝐑}}^4{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{\mathbb{𝕍}(st)}& ={\underset{\_}{\mathbb{\mathbb{Q}}}}_{\mathbb{𝕍}(st)}\\ {\mathbf{𝐑}}^k{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{\mathbb{𝕍}(st)}& ={\underset{\_}{0}}_{\mathbb{𝕍}(st)}\text{ otherwise}\end{array}}$

while over ${\displaystyle {\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}$ we have the local systems

${\displaystyle \begin{array}{rl}{\mathbf{𝐑}}^0{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}& ={\underset{\_}{\mathbb{\mathbb{Q}}}}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}\\ {\mathbf{𝐑}}^1{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}& ={\underset{\_}{\mathbb{\mathbb{Q}}}}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}^{\oplus 2g}\\ {\mathbf{𝐑}}^2{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}& ={\underset{\_}{\mathbb{\mathbb{Q}}}}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}\\ {\mathbf{𝐑}}^k{f}_{!}({\underset{\_}{\mathbb{\mathbb{Q}}}}_X){|}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}& ={\underset{\_}{0}}_{{\mathbb{𝔸}}_{s,t}^2-\mathbb{𝕍}(st)}\text{ otherwise}\end{array}}$

where ${\displaystyle g}$ is the genus of the plane curve (which is ${\displaystyle g=(\mathrm{deg}(f)-1)(\mathrm{deg}(f)-2)/2}$).

The cohomology with local coefficients in the module corresponding to the orientation covering can be used to formulate Poincaré duality for non-orientable manifolds: see Twisted Poincaré duality.

• Leray spectral sequence
• Gauss–Manin connection
• D-module
• Intersection homology
• Perverse sheaf

• "What local system really is". Stack Exchange. https://math.stackexchange.com/q/13332. 
• Schnell, Christian. "Computing Cohomology of Local Systems". https://www.math.stonybrook.edu/~cschnell/pdf/notes/locsys.pdf.  Discusses computing the cohomology with coefficients in a local system by using the twisted de Rham complex.
• Williamson, Geordie. "An illustrated guide to perverse sheaves". http://people.mpim-bonn.mpg.de/geordie/perverse_course/lectures.pdf. 
• MacPherson, Robert (December 15, 1990). "Intersection homology and perverse sheaves". http://faculty.tcu.edu/gfriedman/notes/ih.pdf. 
• El Zein, Fouad; Snoussi, Jawad. "Local systems and constructible sheaves". https://webusers.imj-prg.fr/~fouad.elzein/elzein-snoussif.pdf. 

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