Translation:Disquisitiones Arithmeticae/First Section
On Congruent Numbers in General
Article 1
[edit]Congruent numbers, moduli, residues and non-residues
If a number divides the difference of two numbers and then and are said to be congruent modulo otherwise they are incongruent: the number will be called the modulus of the congruence. In the former case, the numbers and are said to be residues of each other, and in the latter case they are said to be non-residues.
These notions apply to all integers, both positive and negative[1], but they are not to be extended to fractions.
E.g. and are congruent with respect to the modulus is a residue of with respect to the modulus and a non-residue with respect to the modulus
Additionally, since is divisible by any number, it follows that every number must be considered as congruent to itself with respect to any modulus.
Article 2
[edit]All residues of a given number modulo are included in the formula where is an undetermined integer. The simplest of the propositions that we are going to present can be easily demonstrated in this way; but indeed their truth can be equally easily discerned by anyone who looks at them.
From now on, we will denote congruences between two numbers using the symbol adding, when necessary, the modulus enclosed in parentheses, e.g. [2].
Article 3
[edit]Theorem. Given successive integers
and another one and only one of them will be congruent to modulo
If is an integer, we will have If it is a fraction, let be the next largest integer (or the next smallest, if it is negative and the sign is disregarded). Then will necessarily fall between and and thus it will be the number which is sought. Moreover, it is clear that the quotients etc. are between and therefore no more than one of them can be an integer.
Article 4
[edit]Minimal residues.
It follows that every number will have a residue in the sequence and also in the sequence We will call these minimal residues. It is clear that, unless is a residue of the number, there will always be two minimal residues, one positive and the other negative. If their magnitudes are not equal, then one of them will be otherwise, both will be the sign being disregarded; hence it follows that any number has a residue that does not exceed half the modulus, and we will call this the absolute minimum.
E.g. modulo has minimal positive residue which is also absolutely minimal, and also which is the negative minimal residue; modulo is its own minimal positive residue; is the minimal negative residue, which is also the absolute minimum.
Article 5
[edit]Elementary propositions about congruences
From the notions we have just established, we immediately draw the following conclusions:
Numbers that are congruent with respect to a composite modulus are also congruent modulo any of its divisors.
If several numbers are congruent with respect to the same modulus, then they will also be congruent to each other (with respect to that modulus).
The same modulus is assumed throughout the following.
Congruent numbers have the same minimal residues; incongruent numbers have different ones.
Article 6
[edit]Given numbers etc., and as many others etc., and any modulus whatsoever,
If etc., then etc. etc.
If then
Article 7
[edit]If then also
If is a positive number, then this is just a particular case of the previous article, with etc., etc. If is negative, then will be positive; so and therefore
If then For indeed,
Article 8
[edit]If numbers etc. and etc. are pairwise congruent, then the products etc. and etc. will also be congruent.
By the previous article, for the same reason and so on.
If the numbers etc. are assumed to be equal, and so are the numbers etc., then we obtain the following theorem: If and is a positive integer, then
Article 9
[edit]Let be an algebraic function of the variable of the form
where etc. are arbitrary integers, and are non-negative integers. If one gives congruent values to then the resulting values for will also be congruent.
Let and be congruent values of by the previous article and , and similarly etc. Therefore,
Moreover, it is easy to understand how this theorem can be extended to functions of several variables.
Article 10
[edit]Thus if one substitutes consecutive integers in place of and the values of are reduced to their minimal residues, they will form a sequence in which, after an interval of terms ( being the modulus), the same terms will reappear; that is, this sequence will be formed from a period of terms, repeated ad infinitum. For example, let and Then for etc., the values of yield minimal positive residues etc., where the first five terms are repeated ad infinitum; and if the series is continued in the opposite direction, that is, if negative values are assigned to the same period reappears with the order of the terms inverted. From this it is clear that the series does not contain any terms other than those that make up the period.
Article 11
[edit]In this example, therefore, cannot become nor and even less or From this it follows that the equations and can have no integer solutions, and consequently no rational solutions. It can be seen in general that when is of the form
with etc. being integers, and being a positive integer, that the equation (to which form it is clear that any algebraic equation can be reduced) will have no rational roots, if it happens that for a certain modulus the congruence cannot be satisfied; but this criterion, which arises here by itself, will be further developed in section VIII. At least from this example one can form some idea of the utility of these investigations.
Article 12
[edit]Some applications
Several of the theorems that are usually presented in arithmetic treatises rely on those we have presented; for example, the rule to recognize if a number is divisible by or any other number. Modulo all powers of are congruent to unity; therefore if the proposed number is of the form etc., then its minimal residue modulo will be the same as that of etc. From this it is clear that if we add the digits of the number, disregarding the place that they occupy, the sum we obtain will have the same minimal residue as the original number, so that if the latter is divisible by the sum of the digits will be as well, and conversely. The same applies to the divisor Since modulo we will generally have and thus a number of the form etc. will have the same minimal residue as etc.; hence the well-known rule is derived immediately. All similar rules can be easily deduced from the same principle.
The above also explains the reason for the rules that are usually prescribed for verifying arithmetic operations. If some given numbers must be deduced from others by addition, subtraction, multiplication, or raising to powers, we simply substitute in the operations, in place of the given numbers, their minimal residues with respect to an arbitrary modulus (by arbitrary, I really mean or because in the decimal system, as we have just seen, we can easily find the residues relative to these moduli). The resulting numbers must be congruent to those obtained from the given numbers, otherwise it is concluded that a defect has crept into the calculation.
But since these and the like are abundantly well known, it would be superfluous to dwell on them for too long.
- ↑ It is clear that the modulus must be taken absolutely, i.e. without regard to sign.
- ↑ We adopted this symbol because of the great analogy that exists between equality and congruence. It is for the same reason that Legendre, in papers that we will often have occasion to cite, used the very symbol of equality to denote congruence; we preferred another one to prevent any ambiguity.