We study about the metamathematics of Zermelo-Fraenkel set theory with the axiom of choice. We use the validity of Addition and Multiplication. We provide an example that the two operations Addition and Multiplication do not commute with each other. All analyses are performed in a finite set of natural numbers.

Set Theory Formalism
1. Introduction

Zermelo-Fraenkel set theory with the axiom of choice, commonly abbreviated ZFC, is the standard form of axiomatic set theory and as such is the most common foundation of mathematics. It has a single primitive ontological notion, that of a hereditary well-founded set, and a single ontological assumption, namely that all individuals in the universe of discourse are such sets. ZFC is a one-sorted theory in first-order logic. The signature has equality and a single primitive binary relation, set membership, which is usually denoted Î. The formula means that the set a is a member of the set b (which is also read, “a is an element of b” or “a is in b”). Most of the ZFC axioms state that particular sets exist. For example, the axiom of pairing says that given any two sets a and b there is a new set containing exactly a and b. Other axioms describe properties of set membership. A goal of the ZFC axioms is that each axiom should be true if interpreted as a statement about the collection of all sets in the von Neumann universe (also known as the cumulative hierarchy). The me- tamathematics of ZFC has been extensively studied. Landmark results in this area that is established the in- dependence of the continuum hypothesis from ZFC, and of the axiom of choice from the remaining ZFC axioms  . Mach literature concerning above topic can be seen in Refs.  -  .

We use the validity of Addition and Multiplication. Here we aim to provide an example that the two opera- tions Addition and Multiplication do not commute with each other. All analyses are performed in a finite set of natural numbers.

2. The Two Operations Addition and Multiplication Do Not Commute with Each Other

Assume all axioms of Zermelo-Fraenkel set theory with the axiom of choice is true.

We treat here Addition. We have

Thus we obtain 2. By using the obtained 2, we have

Thus we obtain 3. By repeating this method for an even number time, we have

By repeating this method, we have

Thus we have the following finite set of natural numbers

By using the set (6), we discuss that the two operations Addition and Multiplication do not commute with each other.

We consider a value V which is the sum of the results of trials. Result of trials is 1 or 2. We assume the number of 2 is equal to the number of 1. The number of trials is 2 m. We have

We derive the possible value of the product of the value V. It is

We assign the truth value “1” for the following proposition

We have

The value which is the sum of the results of trials is given by

We assume that the possible value of the actually happened results is 1 or 2. We have

The same value is given by

We only change the labels as and. The possible value of the actually happened results is 1 or 2. We have

and

Here. By using these facts we derive a necessary condition for the value given in (11). We derive the possible value of the product of the value V given in (11). We have the following under the assumption that the two operations Addition and Multiplication commute with each other.

The step (16) to (17) is OK. The step (17) to (18) is valid under the assumption that the two operations Addition and Multiplication commute with each other. The step (18) to (19) is true since we have only changed the label as.

The above inequality (19) is saturated since

and

We derive a proposition concerning the value given in (11) under the assumption that the possible value of the actually happened results is 1 or 2, that is. We derive the following proposition

We do not assign the truth value “1” for the two propositions (10) and (24) simultaneously. We are in a contradiction. Thus we have to give up the assumption that the two operations Addition and Multiplication commute with each other.

3. Conclusion

In conclusions, we have used the validity of Addition and Multiplication. We have provided an example that the two operations Addition and Multiplication do not commute with each other. All analyses have been performed in a finite set of natural numbers.

Cite this paper

Koji Nagata,Tadao Nakamura, (2015) Do the Two Operations Addition and Multiplication Commute with Each Other?. Open Access Library Journal,02,1-4. doi: 10.4236/oalib.1101803

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