Image (mathematics)

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In mathematics, the image of a preimage under a given function is the set of all possible function outputs when taking each element of the preimage, successively, as the function's argument.

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[edit] Definition

Let X and Y be sets, f be the function f : XY, and x be some member of X. Then the image of x under f, denoted f(x), is the unique member y of Y that f associates with x. The image of a function f is denoted im(f) and is the range of f, or more precisely, the image of its domain.

The image of a subset AX under f is the subset of Y defined by

f[A] = {yY | y = f(x) for some xA}.

When there is no risk of confusion, f[A] is sometimes simply written f(A). An alternative notation for f[A], common in the older literature on mathematical logic and still preferred by some set theorists, is f "A.

Given this definition, the image of f becomes a function whose domain is the power set of X (the set of all subsets of X), and whose codomain is the power set of Y. The same notation can denote either the function f or its image. This convention is a common one; the intended meaning must be inferred from the context.

The preimage or inverse image of a set BY under f is the subset of X defined by

f −1[B] = {xX | f(x) ∈ B}.

The inverse image of a singleton, f −1[{y}], is a fiber (also spelled fibre) or a level set.

Again, if there is no risk of confusion, we may denote f −1[B] by f −1(B), and think of f −1 as a function from the power set of Y to the power set of X. The notation f −1 should not be confused with that for inverse function. The two coincide only if f is a bijection.

f can also be seen as a family of sets indexed by Y, which leads to the notion of a fibred category.

[edit] Examples

1. f: {1,2,3} → {a,b,c,d} defined by f(x)=\left\{\begin{matrix} a, & \mbox{if }x=1 \\ d, & \mbox{if }x=2 \\ c, & \mbox{if }x=3. \end{matrix}\right.

The image of {2,3} under f is f({2,3}) = {d,c}, and the range of f is {a,d,c}. The preimage of {a,c} is f −1({a,c}) = {1,3}.


2. f: RR defined by f(x) = x2.

The image of {-2,3} under f is f({-2,3}) = {4,9}, and the range of f is R+. The preimage of {4,9} under f is f −1({4,9}) = {-3,-2,2,3}.


3. f: R2R defined by f(x, y) = x2 + y2.

The fibres f −1({a}) are concentric circles about the origin, the origin, and the empty set, depending on whether a>0, a=0, or a<0, respectively.


4. If M is a manifold and π :TMM is the canonical projection from the tangent bundle TM to M, then the fibres of π are the tangent spaces Tx(M) for xM. This is also an example of a fiber bundle.

[edit] Consequences

Given a function f : XY, for all subsets A, A1, and A2 of X and all subsets B, B1, and B2 of Y we have:

  • f(A1 ∪ A2) = f(A1) ∪ f(A2)
  • f(A1 ∩ A2) ⊆ f(A1) ∩ f(A2)
  • f −1(B1 ∪ B2) = f −1(B1) ∪ f −1(B2)
  • f −1(B1 ∩ B2) = f −1(B1) ∩ f −1(B2)
  • f(f −1(B)) ⊆ B
  • f −1(f(A)) ⊇ A
  • A1A2f(A1) ⊆ f(A2)
  • B1B2f −1(B1) ⊆ f −1(B2)
  • f −1(BC) = (f −1(B))C
  • (f |A)−1(B) = Af −1(B).

The results relating images and preimages to the (Boolean) algebra of intersection and union work for any collection of subsets, not just for pairs of subsets:

  • f\left(\bigcup_{s\in S}A_s\right) = \bigcup_{s\in S} f(A_s)
  • f\left(\bigcap_{s\in S}A_s\right) \subseteq \bigcap_{s\in S} f(A_s)
  • f^{-1}\left(\bigcup_{s\in S}A_s\right) = \bigcup_{s\in S} f^{-1}(A_s)
  • f^{-1}\left(\bigcap_{s\in S}A_s\right) = \bigcap_{s\in S} f^{-1}(A_s)

(here S can be infinite, even uncountably infinite.)

With respect to the algebra of subsets, by the above we see that the inverse image function is a lattice homomorphism while the image function is only a semilattice homomorphism (it does not always preserve intersections).

[edit] See also

[edit] References

This article incorporates material from Fibre on PlanetMath, which is licensed under the GFDL.