The precise statement of the result: if I is a set, A_i and B_i are sets for every i in I, and ${\displaystyle A_{i}<B_{i}}$  for every i in I, then

${\displaystyle \sum _{i\in I}A_{i}<\prod _{i\in I}B_{i},}$ 

where < means strictly less than in cardinality, i.e. there is an injective function from A_i to B_i, but not one going the other way. The union involved need not be disjoint (a non-disjoint union can't be any bigger than the disjoint version, also assuming the axiom of choice). In this formulation, König's theorem is equivalent to the axiom of choice.^[1]

(Of course, König's theorem is trivial if the cardinal numbers m_i and n_i are finite and the index set I is finite. If I is empty, then the left sum is the empty sum and therefore 0, while the right product is the empty product and therefore 1).

König's theorem is remarkable because of the strict inequality in the conclusion. There are many easy rules for the arithmetic of infinite sums and products of cardinals in which one can only conclude a weak inequality ≤, for example: if ${\displaystyle m_{i}<n_{i}}$  for all i in I, then one can only conclude

${\displaystyle \sum _{i\in I}m_{i}\leq \sum _{i\in I}n_{i},}$ 

since, for example, setting ${\displaystyle m_{i}=1}$  and ${\displaystyle n_{i}=2}$ , where the index set I is the natural numbers, yields the sum ${\displaystyle \aleph _{0}}$  for both sides, and we have an equality.

• If ${\displaystyle \kappa }$  is a cardinal, then ${\displaystyle \kappa <2^{\kappa }}$ .

If we take m_i = 1, and n_i = 2 for each i in κ, then the left side of the above inequality is just κ, while the right side is 2^κ, the cardinality of functions from κ to {0, 1}, that is, the cardinality of the power set of κ. Thus, König's theorem gives us an alternate proof of Cantor's theorem. (Historically of course Cantor's theorem was proved much earlier.)

Axiom of choice

One way of stating the axiom of choice is "an arbitrary Cartesian product of non-empty sets is non-empty". Let B_i be a non-empty set for each i in I. Let A_i = {} for each i in I. Thus by König's theorem, we have:

• If ${\displaystyle \forall i\in I(\{\}<B_{i})}$ , then ${\displaystyle \{\}<\prod _{i\in I}B_{i}}$ .

That is, the Cartesian product of the given non-empty sets B_i has a larger cardinality than the sum of empty sets. Thus it is non-empty, which is just what the axiom of choice states. Since the axiom of choice follows from König's theorem, we will use the axiom of choice freely and implicitly when discussing consequences of the theorem.

König's theorem and cofinality

König's theorem has also important consequences for cofinality of cardinal numbers.

• If ${\displaystyle \kappa \geq \aleph _{0}}$ , then ${\displaystyle \kappa <\kappa ^{\operatorname {cf} (\kappa )}}$ .

Choose a strictly increasing cf(κ)-sequence of ordinals approaching κ. Each of them is less than κ, so their sum, which is κ, is less than the product of cf(κ) copies of κ.

According to Easton's theorem, the next consequence of König's theorem is the only nontrivial constraint on the continuum function for regular cardinals.

• If ${\displaystyle \kappa \geq \aleph _{0}}$  and ${\displaystyle \lambda \geq 2}$ , then ${\displaystyle \kappa <\operatorname {cf} (\lambda ^{\kappa })}$ .

Let ${\displaystyle \mu =\lambda ^{\kappa }}$ . Suppose that, contrary to this corollary, ${\displaystyle \kappa \geq \operatorname {cf} (\mu )}$ . Then using the previous corollary, ${\displaystyle \mu <\mu ^{\operatorname {cf} (\mu )}\leq \mu ^{\kappa }=(\lambda ^{\kappa })^{\kappa }=\lambda ^{\kappa \cdot \kappa }=\lambda ^{\kappa }=\mu }$ , a contradiction.

Assuming Zermelo–Fraenkel set theory, including especially the axiom of choice, we can prove the theorem. Remember that we are given ${\displaystyle \forall i\in I\quad A_{i}<B_{i}}$ , and we want to show :${\displaystyle \sum _{i\in I}A_{i}<\prod _{i\in I}B_{i}.}$ 

The axiom of choice implies that the condition A < B is equivalent to the condition that there is no function from A onto B and B is nonempty. So we are given that there is no function from A_i onto B_i≠{}, and we have to show that any function f from the disjoint union of the As to the product of the Bs is not surjective and that the product is nonempty. That the product is nonempty follows immediately from the axiom of choice and the fact that the factors are nonempty. For each i choose a b_i in B_i not in the image of A_i under the composition of f with the projection to B_i. Then the product of the elements b_i is not in the image of f, so f does not map the disjoint union of the As onto the product of the Bs.

• M. Holz, K. Steffens and E. Weitz (1999). Introduction to Cardinal Arithmetic. Birkhäuser. ISBN 3-7643-6124-7.
• König, J. (1904), , in Krazer, Adolf (ed.), Verhandlungen des dritten Internationalen Mathematiker-Kongresses in Heidelberg vom 8. bis 13. August 1904, pp. 144–147, archived from the original on 2015-01-04, retrieved 2014-06-14, reprinted as König, J. (1905), "Zum Kontinuum-Problem", Mathematische Annalen, 60 (2): 177–180, doi:10.1007/BF01677263, S2CID 177788074