−1

In mathematics

Algebraic properties

Multiplying a number by −1 is equivalent to changing the sign of the number – that is, for any x we have . This can be proved using the distributive law and the axiom that 1 is the multiplicative identity: :. Here we have used the fact that any number x times 0 equals 0, which follows by cancellation from the equation :. In other words, :, so (−1) ⋅ x is the additive inverse of x, i.e. , as was to be shown.

The square of −1 (that is −1 multiplied by −1) equals 1. As a consequence, a product of two negative numbers is positive. For an algebraic proof of this result, start with the equation :. The first equality follows from the above result, and the second follows from the definition of −1 as additive inverse of 1: it is precisely that number which when added to 1 gives 0. Now, using the distributive law, it can be seen that :. The third equality follows from the fact that 1 is a multiplicative identity. But now adding 1 to both sides of this last equation implies :. The above arguments hold in any ring, a concept of abstract algebra generalizing integers and real numbers.

Although there are no real square roots of −1, the complex number i satisfies , and as such can be considered as a square root of −1. The only other complex number whose square is −1 is −i because there are exactly two square roots of any non‐zero complex number, which follows from the fundamental theorem of algebra. In the algebra of quaternions – where the fundamental theorem does not apply – which contains the complex numbers, the equation has infinitely many solutions.

Inverse and invertible elements

Exponentiation of a non‐zero real number can be extended to negative integers, where raising a number to the power −1 has the same effect as taking its multiplicative inverse: :.

This definition is then applied to negative integers, preserving the exponential law for real numbers a and b.

A −1 superscript in f −1(x) takes the inverse function of f(x), where ( f(x))−1 specifically denotes a pointwise reciprocal. Where f is bijective specifying an output codomain of every y ∈ Y  from every input domain x ∈ X, there will be

: and .

When a subset of the codomain is specified inside the function f, its inverse will yield an inverse image, or preimage, of that subset under the function.

Exponentiation to negative integers can be further extended to invertible elements of a ring by defining x−1 as the multiplicative inverse of x; in this context, these elements are considered units.

In a polynomial domain F [x] over any field F, the polynomial x has no inverse. If it did have an inverse q(x), then there would be : : : which is not possible, and therefore, F [x] is not a field. More specifically, because the polynomial is not constant, it is not a unit in F.

References

Notes

Sources

References

1. Nathanson, Melvyn B.. (2000). "Elementary Methods in Number Theory". [[Springer Science+Business Media.
2. Bauer, Cameron. (2007). "Algebra for Athletes". [[Nova Science Publishers]].
3. Perlis, Sam. (1971). "Historical Topics in Algebra". [[National Council of Teachers of Mathematics]].
4. Porteous, Ian R.. (1995). "Clifford Algebras and the Classical Groups". [[Cambridge University Press]].
5. (1992). "Algorithms for Computer Algebra". Kluwer Academic Publishers.