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Definition
Let f be a function whose domain is a set A. The function f is injective if, for all a and b in A, if f(a) = f(b) then a = b.
Examples and counter-examples
- For any set X, the identity function on X is injective.
- The function f : R → R defined by f(x) = 2x + 1 is injective.
- The function g : R → R defined by g(x) = x2 is not injective, because (for example) g(1) = 1 = g(−1). However, if g is redefined so that its domain is the non-negative real numbers [0,+∞), then g is injective.
- The exponential function exp : R → R defined by exp(x) = ex is injective (but not surjective as no value maps to a negative number).
- The natural logarithm function ln : (0, ∞) → R defined by x ↦ ln x is injective.
- The function g : R → R defined by g(x) = xn − x is not injective, since, for example, g(0) = g(1).
More generally, when X and Y are both the real line R, then an injective function f : R → R is one whose graph is never intersected by any horizontal line more than once.
Injections can be undone
Functions with left inverses are always injections. That is, given f : X → Y, if there is a function g : Y → X such that, for every x ∈ X
- g(f(x)) = x (f can be undone by g)
then f is injective. In this case, f is called a section of g and g is called a retraction of f.
Conversely, every injection f with non-empty domain has a left inverse g (in conventional mathematics[1]). Note that g may not be a complete inverse of f because the composition in the other order, f ∘ g, may not be the identity on Y. In other words, a function that can be undone or "reversed", such as f, is not necessarily invertible (bijective). Injections are "reversible" but not always invertible.
Although it is impossible to reverse a non-injective (and therefore information-losing) function, you can at least obtain a "quasi-inverse" of it, that is a multiple-valued function.
Injections may be made invertible
In fact, to turn an injective function f : X → Y into a bijective (hence invertible) function, it suffices to replace its codomain Y by its actual range J = f(X). That is, let g : X → J such that g(x) = f(x) for all x in X; then g is bijective. Indeed, f can be factored as inclJ,Y ∘ g, where inclJ,Y is the inclusion function from J into Y.
Other properties
- If f and g are both injective, then f ∘ g is injective.
- If g ∘ f is injective, then f is injective (but g need not be).
- f : X → Y is injective if and only if, given any functions g, h : W → X, whenever f ∘ g = f ∘ h, then g = h. In other words, injective functions are precisely the monomorphisms in the category Set of sets.
- If f : X → Y is injective and A is a subset of X, then f −1(f(A)) = A. Thus, A can be recovered from its image f(A).
- If f : X → Y is injective and A and B are both subsets of X, then f(A ∩ B) = f(A) ∩ f(B).
- Every function h : W → Y can be decomposed as h = f ∘ g for a suitable injection f and surjection g. This decomposition is unique up to isomorphism, and f may be thought of as the inclusion function of the range h(W) of h as a subset of the codomain Y of h.
- If f : X → Y is an injective function, then Y has at least as many elements as X, in the sense of cardinal numbers.
- If both X and Y are finite with the same number of elements, then f : X → Y is injective if and only if f is surjective.
- Every embedding is injective.
See also
Notes
- ^ This principle is valid in conventional mathematics, but may fail in constructive mathematics. For instance, a left inverse of the inclusion {0,1} → R of the two-element set in the reals violates indecomposability by giving a retraction of the real line to the set {0,1}.
References
- Bartle, Robert G. (1976), The Elements of Real Analysis (2nd ed.), New York: John Wiley & Sons, ISBN 978-0-471-05464-1, p. 17 ff.
- Halmos, Paul R. (1974), Naive Set Theory, ISBN 978-0-387-90092-6, p. 38 ff.
