Translation:Disquisitiones Arithmeticae/Second Section
On Congruences of the First Degree
Article 13
[edit]Preliminary theorems about prime numbers, factorizations, etc.
Theorem. The product of two positive numbers, each of which is smaller than a given prime, cannot be divisible by this prime.
Let be the prime, and let be a positive number then it is not possible to find a number smaller than such that
Proof. If anyone denies it, let us suppose that numbers etc. are given, all of which are less than such that etc. Let be the smallest of these, so that all numbers smaller than are deprived of this property. Clearly for if then we would have so would not be divisible by Now, as a prime number, cannot be divisible by and must instead fall between two multiples of and Let Then will be positive and Since we have assumed it is also true that (Art. 7), and hence subtracting from we will have ; i.e. is included among the numbers etc., even though was supposed to be the smallest of them. Q.E.A.
Article 14
[edit]If neither nor is divisible by a given prime number then the product will also not be divisible by .
Let and be the minimal positive residues of the numbers and modulo By hypothesis, neither of these will be zero. Now, if it were true that then since it would also be true that But this is impossible, by the previous theorem.
The proof of this theorem has already been given by Euclid, Elements, vii, 32. However, we did not want to omit it, both because several modern authors have presented vague reasoning instead of a proof, or have neglected this theorem; and also because the nature of the method used here, which we will later apply to much more difficult problems, can be more easily understood from a simpler case.
Article 15
[edit]If none of the numbers is divisible by the prime number then the product etc. will also not be divisible by .
According to the previous article, is not divisible by so the same is true for hence also for etc.
Article 16
[edit]Theorem. A composite number can only be resolved into prime factors in one way.
Proof. It is evident from first principles that any number can always be decomposed into prime factors; but it is often tacitly assumed that this decomposition is only possible in one way. Let us imagine a composite number etc., where etc. are unequal prime numbers, and suppose that can be resolved into prime factors in yet another way. It is first of all clear that in this second system of factors, primes other than etc. cannot enter, since these are the only primes which divide . Similarly, none of the prime numbers etc. can be missing, because if that were the case, the missing primes would not divide (Art. 15); thus the two factorizations can only differ insofar as a prime is repeated more times in one than in the other. Let be a prime number, which is repeated times in one system and times in the other, with . Now let the factor be removed from each system times, so that it remains in one system times, and has disappeared from the other. Then the number has two different factorizations, one of which is completely free of the factor , while the other still contains it times, contrary to what we have just shown.
Article 17
[edit]Therefore, if a composite number is the product of etc., then it is clear that the numbers etc. cannot have prime factors different from those of and that each of these factors must occur as many times altogether in the numbers etc. as it does in From this, one obtains a criterion to determine whether one number divides another number This will happen if does not involve any prime more times than if this condition is not satisfied, then will not divide
With the help of the calculus of combinations, it is easy to see that if etc., where as above etc. denote distinct prime numbers, then has
distinct divisors, including and
Article 18
[edit]It is therefore clear that if etc., etc., and if the primes etc., etc. are all distinct from one another, then and will have no common divisor other than or in other words they will be relatively prime.
Given several numbers etc., their greatest common divisor is determined as follows. The numbers are resolved into their prime factors, and those that are common to all the numbers etc. are taken (if there are none, the given numbers would have no common divisor). Then one notes how many times each of these prime factors is contained in etc., or equivalently the exponents of these factor in each of the numbers etc. Then each factor is given the smallest of the exponents that it has in etc. Finally, the product of the resulting powers is computed; this will be the greatest common divisor.
On the other hand, if the least common multiple of the numbers etc. is desired, one can proceed as follows. Collect all the prime numbers that divide any of the numbers etc., and assign to each of them the largest exponent that it has in the numbers etc. The product of all these powers will be the required common multiple.
Ex. Let . To find the greatest common divisor, the prime factors and which must be assigned exponents and this gives the greatest common divisor the least common multiple will be
We omit the proofs because of their simplicity; after all, it is known how to solve these problems in an elementary way, even when the factorizations of the numbers etc. are not given.
Article 19
[edit]If the numbers etc. are relatively prime to then their product will also be relatively prime to
Indeed, because none of the numbers etc. has prime factors in common with the product etc. cannot have prime factors that do not belong to any of etc. Thus from the previous article, etc. will be relatively prime to
If the numbers etc. are relatively prime to each other, and is divisible by each of them, then is also divisible by their product.
This is easily derived from Arts. 17 and 18. Let be any prime divisor of the product etc., which is repeated times. Then it is clear that one of the numbers etc. will be divisible by and consequently which is divisible by this number, will also be divisible by . The same reasoning holds for the remaining divisors of the product etc.
Therefore, if two numbers are congruent modulo several relatively prime moduli etc. then they will also be congruent modulo the product. Indeed, since is divisible by each of the numbers etc., it must also be divisible by their product.
Finally, if is relatively prime to and is divisible by then will also be divisible by Indeed, since is divisible by and it will be divisible by their product, i.e. will be an integer.
Article 20
[edit]If etc., where etc. are distinct prime numbers, and is equal to a perfect power then all of the exponents etc. will be divisible by
The number does not involve prime numbers other than etc. Let be the exponent of in Then will contain this factor times, so and is an integer. It can be shown in a similar way that etc. are integers.
Article 21
[edit]If etc. are relatively prime to each other, and their product etc. is a perfect power then each number etc. will also be an th power.
Let etc., where etc. are distinct prime numbers, none of which (by hypothesis) divide any of the numbers etc. Then the product etc. will include as a factor times, as a factor times, etc.: hence (by the previous article) will all be divisible by and therefore
will be an integer. The same will be true for etc.
These facts about prime numbers having been put forth, we now turn to other things which will lead us more directly to our goal.
Article 22
[edit]If the numbers and are divisible by and are congruent with respect to a modulus that is relatively prime to then and are congruent with respect to that same modulus.
It is clear that is divisible by and also by (by hypothesis); thus will be divisible by (Art. 19), i.e.
If the numbers and instead have a common divisor then we will have . For and are relatively prime, and is divisible by and by so is divisible by and by and therefore by i.e. is divisible by or equivalently
Article 23
[edit]If numbers and are relatively prime, and numbers and are incongruent modulo then and will also be incongruent modulo .
This is a restatement of the theorem of the preceding article.
Hence it is clear that if we multiply all of the integers from to by , and reduce these products to their minimal residues modulo the resulting residues will all be distinct. Since the number of these residues is and none of them is it is also clear that every integer in the series from to will be found among them.
Article 24
[edit]The expression in which and are given numbers and is an indeterminate or variable number, can be made congruent to any given number modulo provided that is relatively prime to
Let be the number to which it must be congruent, and let the minimal positive residue of By the preceding article, it is possible to find a value such that the minimal residue of the product modulo is equal to let be this value. Then thus Q.E.F.
Article 25
[edit]We will call any expression which takes the form of an equation, and relates two congruent quantities, a congruence; if it contains an unknown, to solve it means to find a value for this unknown which satisfies the congruence (a root). By this we understand what it means for a congruence to be solvable or unsolvable. It is easy to see that the same distinctions that apply to equations can also be applied congruences. Later we will see examples of transcendental congruences; as for algebraic congruences, they are divided according to the highest power of the unknown, into congruences of the first, second, and higher degree. One can even propose several congruences containing several unknowns, to which elimination must be applied.
Article 26
[edit]Solution of congruences of the first degree
From Art. 24 it follows that first degree congruences are always solvable, provided that the modulus is relatively prime to In this case, let be the appropriate value for or the root of the congruence. Then it is clear that all numbers congruent to modulo , will also be roots (Art. 9). It is equally clear that all roots must be congruent to for if is another root, then we have so and thus (Art. 22). We conclude from this that the congruence gives the complete solution to the congruence
Since the congruence is solved by values of which are all congruent to each other, and in this context congruent numbers must be considered equivalent, we will consider these solutions as one and the same. Therefore, since our congruence does not admit any other solutions, we say that it can only be solved in one way or has only one root. So e.g. the congruence does not admit any roots other than those which are The situation is different for higher degree congruences, and even for first degree congruences where the coefficient of the unknown is not relatively prime to the modulus.
Article 27
[edit]It remains for us to add some details about how to solve this kind of congruence. First, observe that any congruence of the form in which the modulus is assumed to be relatively prime to can be reduced to the congruence For if satisfies the latter, then will satisfy the former. But the congruence , whose modulus is denoted by is equivalent to the indeterminate equation whose solution is known; therefore it will be sufficient for us to provide an algorithm by which this calculation can be carried out.
If quantities etc. depend on others etc. in such a way that
then for the sake of brevity we write[1]
Now, consider the equation where and are positive. Suppose, as is permitted, that is not less than Then, according to the well-known algorithm for finding the greatest common divisor of two numbers, the following equations will be formed by division,
so that etc. are positive integers, and etc. are continually decreasing, until we reach which must always happen. Then we will have
Setting
we will have when the number of quantities is even, and when it is odd.
Article 28
[edit]The general solution of these equations was first given by Euler, Comment. de Petersb. T. VII, p. 46. The method he used consists of substituting other unknowns in place of and and it is indeed well known. Lagrange treated the problem in a slightly different manner. He observed that if one decomposes the fraction into a continued fraction
then after erasing the last part it reduces to an ordinary fraction and one has so long as and are relatively prime. In fact, the two methods lead to the same algorithm. Lagrange’s investigations can be found in the Histoire de l’Académie de Berlin, Année 1767, p. 175, and along with others in Supplementis versioni gallicae Algebrea Eulerianae adiectis.
Article 29
[edit]The congruence in which the modulus is not relatively prime to is easily reduced to the previous case. Let be the modulus and let be the greatest common divisor of and It is first of all clear that any value of which satisfies the proposed congruence modulo will also satisfy it modulo (Art. 5). But since divides we always have Therefore, we must have i.e. must be divisible by in order for the congruence to be solvable.
Let us therefore set so that and will be relatively prime. Then the proposed congruence will be equivalent to i.e. any value of that satisfies the second one will also satisfy the first one, and vice versa. For it is clear that will be divisible by whenever is divisible by and vice versa. But we have already seen how to solve the congruence hence it is clear that if is one of the values of then gives the complete solution of the proposed congruence.
Article 30
[edit]When the modulus is composite, it is often advantageous to use the following method:
Let the modulus and let the proposed congruence First solve the congruence modulo and suppose that it is satisfied for where is the greatest common divisor of the numbers and Now it is evident that any value of which satisfies the congruence will also satisfy the congruence and thus it will be included in the form where denotes an undetermined number. However, not all numbers of this form will satisfy the congruence modulo Rather, the values of must be chosen in such a way that is a root of the congruence hence we will have or equivalently It follows from this that the solution of any congruence of the first degree modulo can be reduced to the solution of two congruences, one modulo and the other modulo It is easy to see that if is the product of two factors, the solution of the congruence modulo depends on the solution of two congruences with these factors as moduli; and generally, the resolution of a congruence modulo any composite modulus depends on the resolution of other congruences, whose moduli are the factors of the first one, and these moduli can always be chosen to be prime numbers, if it seems convenient.
Ex. consider the congruence if we first solve it modulo we get By setting we get or Solving this modulo we get and setting we get or Solving this modulo gives and substituting we have or From this it follows that and thus from which we have therefore is the complete solution of the proposed congruence.
Article 31
[edit]In the same way that the root of the equation is expressed by we will also denote the root of the congruence by including the modulus of the congruence for the sake of clarity. So e.g. represents an arbitrary number which is .[2] It is generally clear from the above that does not have a real meaning in the case where and have a common divisor that does not divide (or, if one prefers, it is imaginary). However, except in this case, the expression will always have real values, and indeed infinitely many, which will all be congruent modulo when is relatively prime to , or more generally modulo where is the greatest common divisor of and
These expressions have almost the same arithmetic as ordinary fractions. Here we add some properties that can be easily deduced from what we have already shown:
- If and modulo then the expressions and are equivalent.
- and are equivalent.
- and are equivalent if is relatively prime to
Many other similar propositions might be added here: but as they are not difficult, and unnecessary for what follows, we now move on to other things.
Article 32
[edit]On finding numbers congruent to given residues with respect to given moduli
A problem which will be of great use in what follows is to find all the numbers which form given remainders according to several given moduli. It is easy to solve this from what has already been presented. Let and be two given moduli, and let us seek a number which is congruent to the numbers and with respect to these moduli, respectively. Then all values of will necessarily be contained in the form where is undetermined, but also satisfies If the greatest common divisor of and is , then the complete solution of this congruence will take the form or equivalently where is an undetermined integer; thus the form contains all values of i.e. the complete solution of the problem will be Now if there were a third modulus relative to which the number must be then it is clear how to proceed in the same way, since the two original conditions have already been merged into one. Namely, letting be the greatest common divisor of the numbers and we will obtain the congruence which can be solved by a congruence of the form Then the problem will be solved by the congruence One can proceed in the same way, regardless of the number of moduli. It is worth noting that and are the least numbers divisible by and by respectively. Thus one easily deduces, regardless of the number of moduli etc., that if denotes the smallest number divisible by all of them, then the complete solution will be of the form Moreover, if one of the congruences is not solvable, it must be concluded that the problem is impossible. However, it is evident that this cannot happen if the numbers etc. are all relatively prime to each other.
Ex. Let . Here the first two conditions, and can be reduced to a single condition Combining this with the third condition, one obtains
Article 33
[edit]When the numbers etc. are all relatively prime to each other, their product is the smallest number divisible by each of them; and in this case it is obvious that the congruences etc. together will be equivalent to a single congruence where denotes the product of the numbers etc. Conversely, it follows from this that a single condition can be decomposed into several; namely, if is decomposed into several mutually relatively prime factors etc., then the combined conditions etc. will be equivalent to the original one. This observation gives us not only the means to discover an impossibility when it exists, but also a more convenient and elegant method of calculation.
Article 34
[edit]Let the conditions proposed above be . Resolve all of the moduli into mutually relatively prime factors, into etc.; into etc. etc., so that the numbers etc. etc. etc. are either primes or powers of primes. Of course, if one of the numbers is already prime itself, or a power of a prime number, then it need not be resolved into factors. Then it is clear from the above that, in place of the proposed conditions, one can substitute etc., etc. etc. Now, unless all the numbers etc. are mutually prime, e.g. if and are not relatively prime, then it is clear that the prime divisors of and cannot all be different, and one of the divisors etc. must find its equal, its multiple, or its submultiple among the divisors etc. In the first case, if , then the conditions must be identical, or equivalently then one or the other of these two conditions can be rejected. On the other hand, if does not hold, the problem is impossible. In the second case, if is a multiple of then the condition must be contained in or in other words it can be used to deduce Under these conditions, the condition can be rejected, if it does not contradict the other one (in which case the problem would be impossible). When all the superfluous conditions are thus rejected, it is clear that all the remaining moduli are mutually prime; one is then sure of the possibility of the problem, and one can proceed according to the method given above.
Article 35
[edit]If as above we set and then these conditions can be reduced to the following: From these conditions, we can reject and since the former is contained in the condition and the latter is equivalent to we are then left with
from which we obtain
Now, it is clear that it would often be more convenient if, of the remaining conditions, those which had been derived from one and the same condition were combined into a single condition. This can be done easily; e.g. when some of the conditions etc. have been rejected, the rest can be restored as with respect to the modulus formed by the product of the remaining moduli. Thus in our example the condition can be recovered from the conditions and Now, it does make some difference which of the superfluous conditions are rejected, as far as the brevity of the calculation is concerned. But this is not the place to discuss these details or other practical tricks, which are learned from practice much more easily than from precepts.
Article 36
[edit]When the moduli etc. are mutually relatively prime, it is often preferable to use the following method. Let be a number which is congruent to unity modulo and which is divisible by the product of the other moduli; that is, will be any value (the minimum is generally best) of the expression multiplied by etc. (see Art. 32); similarly, let and and etc. Then to find a number which is congruent to the numbers etc. modulo etc. respectively, we can set
Then we clearly have and the other terms are hence The demonstration is the same for the other moduli. This solution is preferable to the first one when solving several problems of the same kind, for which the values of etc. are the same; for then the values of etc. remain constant. This can be applied to the chronological problem in which we must find the Julian year which has a given indiction, the golden number, and the solar cycle. Here thus the value of the expression or is and we have Similarly, we find hence the desired number will be the minimal residue of the number where denotes the indiction, the golden number, and the solar cycle.
Article 37
[edit]Linear congruences involving several unknowns
Enough has been said about congruences of the first degree which contain only one unknown. It remains to deal with congruences that involve several unknowns, but since it would be too extensive to present everything rigorously in this chapter, and our goal is not to exhaust the subject here, but only to present what is most worthy of attention, we will limit our discussion to a few observations, reserving the complete exposition for another occasion.
1. Just as for equations, it can be seen that there must be as many congruences as there are unknowns for a solution to determined.
2. Let the following congruences be proposed
and assume that the number of these congruences is the same as the number of unknowns etc.
Then determine numbers etc. so that
and so that these numbers are integers with no common divisor (which is always possible, by the theory of linear equations).
In a similar way, determine etc., etc. etc. so that
3. It is clear that if we multiply the congruences etc. first by etc. and then by etc. etc. and add them, we will obtain the following:
For the sake of brevity, we will write these congruences as
4. There are now several cases to distinguish.
First, when the coefficients of the unknowns, etc. are all relatively prime to the modulus , the above congruences can be solved by the methods already presented, and the complete solution of the problem will be given by congruences of the form etc.[3]. E.g. if we propose the congruences
we will find hence and therefore likewise, we will find and hence
5. Second, If the coefficients etc. are not all relatively prime to the modulus, let etc. be the greatest common divisors of and etc. respectively. Then it is clear that the problem is impossible unless the numbers etc. are divisible by etc. respectively. On the other hand, when these conditions hold, the problem will be completely solved by congruences of the form etc., or if you prefer, there will be different values for (i.e. the values which are incongruent modulo ), values for etc. that will satisfy the congruences. Clearly, all solutions to the problem, if there are any, must be found among those we have just indicated. However, it is not allowed to reverse this conclusion; for in general it is not true that all combinations of the values of with those of and those of etc. will satisfy the problem, but only some of them whose connection must be expressed by means of one or more conditional congruences. However, since the complete solution of this problem is not necessary for the following, we will not go any further on this subject and content ourselves to give the idea with an example.
Let the following congruences be proposed:
Then we will have
hence From this we obtain four values of namely, one value of namely and four values of namely, To find out which combinations of the values of and are permissible, substitute for in the given congruences. After this, they become
which are easily seen to be equivalent to
The first congruence clearly requires that and the rest will clearly be satisfies if this value is substituted in them. We conclude from this that the values (which are obtained by successively setting ) must be combined respectively with the values so there are four solutions altogether,
To these investigations, which complete the task we had set ourselves in this section, we will add some propositions based on similar principles, which will be needed frequently in what follows.
Article 38
[edit]Various theorems
Problem. Determine how many numbers are less than and relatively prime to a given positive number
For the sake of brevity, let us denote the number we seek by the prefixed symbol . So, the problem is to find
I. When is prime, it is clear that all numbers from to are relatively prime to therefore, in this case, we have
II. When is a power of a prime number say then all numbers divisible by will not be prime with and the others will be. Therefore, of the numbers, we must reject so there remain Hence
III. The other cases can be easily reduced to these, by means of the following proposition: If we factor into factors etc. which are all relatively prime to each other, then
which can demonstrated as follows. Let etc. be the numbers which are less than and relatively prime to , whose multitude is therefore . Similarly, let the numbers less than and relatively prime to etc. be etc.; etc. etc., whose multitudes are etc. It is clear that any number relatively prime to will also be relatively prime to the factors etc. and vice versa (Art. 19). Furthermore, all numbers that are congruent to one of the numbers etc. modulo will be relatively prime to and the same applies for etc. The question is therefore reduced to determining how many numbers are less than and congruent to one of the numbers etc. modulo to one of the numbers etc. modulo , etc. However, it follows from Art. 32 that all numbers with given residues modulo etc. must be congruent modulo the product and therefore there can only be one number less than which is congruent to the given residues modulo etc. Therefore, the number we seek will be equal to the number of combinations of the individual numbers etc. with the individual numbers etc. and etc. etc. It is evident from the theory of combinations that this number is etc. Q.E.D.
IV. It is easy to see how to apply this proposition in the case at hand. We will decompose into prime factors; that is, we will reduce it to the form etc., with etc. being distinct prime numbers. Then we will have
which can be put in the more elegant form
Example: Take Then we have The numbers which are less than and relatively prime to are
The first solution of this problem can be found in Euler’s commentary, Theoremata arithmetica nova methodo demonstrata, Comm. nov. Ac. Petrop. VIII p. 74. A demonstration was also provided in another dissertation Speculationes circa quasdam insignes proprietates numerorum Acta Petrop. VIII, p. 17.
Article 39
[edit]If the meaning of the symbol is determined in such a way that expresses how many numbers are relatively prime to and not greater than then we will have instead of However, in all other cases, nothing will change. Adopting this definition, we have the following theorem:
If etc. are all of the divisors of including 1 and then
Ex. If we have
Proof. If we multiply all numbers coprime with and not greater than by and similarly all numbers coprime with by etc., then we will have etc. numbers, all of which are not greater than However,
- All of these numbers will be distinct. Indeed, it is clear that those coming from the same divisor of are all distinct. On the other hand, if two equal numbers resulted from different divisors and and from numbers and respectively, that is, if then we would have Assuming that (which is allowed), then since is relatively prime to and divides it would follow that the larger number divides the smaller number Q.E.A.
- Among these numbers, we will find all of those which make up the sequence Indeed, let be any number that does not exceed and let be the greatest common divisor of and Then will be a divisor of which is relatively prime to . Then clearly the number will be among those that were produced by the divisor .
- It follows from this that the multitude of these numbers is and hence
Q.E.D.
Article 40
[edit]If is the greatest common divisor of the numbers etc., then numbers etc. can be determined so that
Let us first consider only two numbers and and let be their greatest common divisor. Then the congruence will be solvable (Art. 30). Let the root be and set Then we will have as desired.
If there is a third number let be the greatest common divisor of and Note that will also be the greatest common divisor of the three numbers .[4] Then let numbers and be determined so that and we will have
If there is a fourth number let be the greatest common divisor of and (which, it is easily seen, will also be the greatest common divisor of the four numbers and ). Then let and we will have
We would proceed in a similar way if there were more numbers.
In particular, if the numbers etc. have no common divisor, then it is clear that we can find etc. so that
Article 41
[edit]If is a prime number, and if there are objects among which any number may be equal (provided that they are not all equal), then the number of permutations of these objects will be divisible by
For example, five objects can be arranged in ten different ways.
The demonstration of this theorem is easily deduced from the well-known theory of permutations. Indeed, suppose that, among these things, there are equal to equal to equal to etc. (where the numbers can also represent unity), so that we have
Then the number of permutations will be
It is clear that the numerator of this fraction is divisible by the denominator, since the number of permutations is an integer: but the numerator is divisible by whereas the denominator, which is composed of factors smaller than is not divisible by (Art. 15). Therefore, the number of permutations will be divisible by (Art. 19).
That being said, we hope that the following demonstration will not be unwelcome.
When in two permutations the order of the objects only differs in that the item which occupied the first place in one, now occupies a different one in the other, while the other objects, starting from that one, follow the same order in each of the permutations, so that the last item in one is immediately before the first item in the other. Then we will call them similar permutations[5]. So, for example, the permutations and will be similar, since the things which in the former occupy the first place, second place, etc. occupy the third place, fourth place, etc. in the latter.
Now, as each permutation consists of objects, it is clear that one can find similar permutations, if one puts successively at the second place, third place, etc. the item which occupied the first place. Therefore, if none of these similar permutations are identical, it is evident that the total number of permutations will be equal to times the number of dissimilar permutations, and consequently will be divisible by Let us suppose, then, that two similar permutations
one of which has arisen from the other by the promotion of terms, are identical, in the sense that etc. Suppose that the term which occupies the first place in the first permutation, occupies the in the second. Then in the latter series, the term will be equal to the first, the will be equal to the second, etc., from which it follows that the will again be equal to the first, and likewise for the and in general the will be equal to the (where, when it is necessary to imagine that either the series is repeated from the beginning, or that we subtract a multiple of from ). Therefore, if we determine in such a way that which can always be done since is prime, it will follow that generally the term will be equal to the i.e. all the terms will be equal to each other, contrary to the hypothesis.
Article 42
[edit]If the coefficients of two functions of the form
are all rational, but not all integers, and their product is
then the coefficients cannot all be integers.
Indeed, let us simplify to their simplest form all fractions that may be found among the numbers etc. etc., and choose a prime number that divides one or more of the denominators of these fractions. Let us assume, as we may, that divides the denominator of a fractional coefficient in It is clear that if is divided by then at least one fractional coefficient in will have a denominator divisible by (in particular, the coefficient of the first term will be ). It is then easy to see that in there is a term whose denominator contains a power of raised to a power which is greater than in all of the preceding terms, and not less than in all of the terms which follow. Let be such a term, and let be the exponent of in its denominator. Let the analogous term in be and let the exponent of in the denominator be Then clearly will be at least With this in mind, the term of the product of and will have a fractional coefficient whose denominator contains raised to the power as will now be shown.
Let etc. be the terms preceding in and let etc. be those which follow it. Similarly, let etc. be the terms preceding in and let be those which follow it. Then in the product of and the coefficient of will clearly be
The term will be a fraction which, when reduced to its simplest form, will have a denominator divisible by If the other terms are fractional, then their denominators will contain only powers of less than since each of them is the product of two factors, one of which contains only a power of smaller than or and the other a power not greater than or Thus will be of the form and the rest will be of the form where and are relatively prime to Therefore the sum of these will be a fraction whose numerator is not divisible by Hence this fraction cannot be reduced in any way so that its denominator contains a a power of smaller than Therefore, the coefficient of the term in the product of by will be
i.e. a fraction, whose denominator is divisible by at least the power of Q.E.D.
Article 43
[edit]A congruence of the degree,
whose modulus is a prime number that does not divide cannot have more than solutions, or equivalently cannot have more than incongruent roots modulo (See Arts. 25, 26).
If anyone denies it, let us suppose that congruences of different degrees etc. are given, which have more than etc. roots. Let be the smallest of all of these, so that all congruences of degree lower than are consistent with our theorem. Since it has already been demonstrated above (Art. 26) that the theorem holds for congruences of the first degree, it is clear that will be or greater. Let us therefore assume that the congruence
has at least roots etc., and suppose that all of the numbers etc. are positive and less than , with the smallest being . Now let us substitute for in the proposed congruence, with the result being
Then it is clear that this congruence will be satisfied if we put or or etc., and that all of these roots will be distinct, with their multitude being However, since is a root, it follows that is divisible by From this we obtain
a congruence that will be satisfied by substituting for any of the values etc. which are all and and therefore in these cases
will become (Art. 22), i.e. the congruence
which is of degree would have roots; which contradicts our theorem (for it is easy to see that and therefore it is not divisible by as required), even though we assumed that all congruences of a degree lower than satisfy it. Q.E.A.
Article 44
[edit]Although we have assumed here that the modulus does not divide the coefficient of the first term, the theorem is not restricted to this case. For if the first coefficient, and even some of the following ones, were divisible by then these terms could be neglected without error, and the congruence would be reduced to a lower degree, such that the coefficient of the first term would no longer be divisible by Indeed, not all coefficients can be divisible by ; in this case the congruence would be an identity, and the unknown would be completely indeterminate.
Lagrange was the first to propose and prove the theorem (Mem. de l'Ac de Berlin, Année 1768 p.192). It is also found in Legendre’s dissertation, Recherches d’Analyse indéterminée, Hist. de l'Acad. de Paris 1785 p. 466). Euler proved, in Nouveaux Commentaires Académiques. Pétersb. XVIII, p. 93, that the congruence could not have more than roots. Although this is only a particular case, his method can easily be applied to all congruences. He had already dealt with a still more limited case, Comm. nov. Ac. Petr. V. p. 6, but this method cannot be used in general. In Section VIII below, we will demonstrate this theorem in yet another way; but no matter how different all these methods may seem at first glance, experts who wish to compare them will easily verify that they all originate from the same principle. Furthermore, this theorem should only be considered here as a lemma, and the complete exposition does not belong to this section, so we will treat the case of a composite modulus elsewhere.
- ↑ This relationship of quantities can be considered in a much more general manner, and we may do so on another occasion. Here we will add only two propositions, which find their application in the present question, namely:
- 1.
- 2. The order of the quantities can be reversed, so that
- ↑ This could just as well be denoted by
- ↑ It should be noted that this conclusion lacks a demonstration, which we omit here. Strictly speaking, nothing follows from our analysis other than that the proposed congruences cannot be solved by other values of etc. but not necessarily that these values satisfy the congruences; it is even possible that there may be no solution. The same fallacy arises in solving linear equations.
- ↑ It is clear that divides each of the numbers If it were not the greatest common divisor of then there would be one greater than However, this one would divide , i.e. Q.E.A. This can still more easily be deduced from Art. 18
- ↑ If one were to write the similar permutations in a circle, in such a way that the last item is adjacent to the first, then there would be no difference between them, because no place could be called the first or the last