Difference between revisions of "Pell equation"
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Let <math>(x_{0}, y_{0})</math> be the minimal solution to the equation <math>x^2-Dy^2 = 1</math>. Note that if <math>(a,b), (c, d)</math> are solutions to this equation then <math>(a^2-Db^2)(c^2-Dd^2) = (ac+Dbd)^2-D(cb+ad)^2 = 1</math> which means <math>(ac+Dbd, cb+ad)</math> is another solution. From this we can guess that <math>(x_{n}, y_{n})</math> is obtained from <math>(x_{0}^2-Dy_{0}^2)^{n+1}</math>. This does indeed generate all the solutions to this equation. Assume there was another solution <math>(p, q)</math>. Then there exists some m such that | Let <math>(x_{0}, y_{0})</math> be the minimal solution to the equation <math>x^2-Dy^2 = 1</math>. Note that if <math>(a,b), (c, d)</math> are solutions to this equation then <math>(a^2-Db^2)(c^2-Dd^2) = (ac+Dbd)^2-D(cb+ad)^2 = 1</math> which means <math>(ac+Dbd, cb+ad)</math> is another solution. From this we can guess that <math>(x_{n}, y_{n})</math> is obtained from <math>(x_{0}^2-Dy_{0}^2)^{n+1}</math>. This does indeed generate all the solutions to this equation. Assume there was another solution <math>(p, q)</math>. Then there exists some m such that | ||
− | <math>x_{m}+\sqrt{D}y_{m} < p+\sqrt{D}q < x_{m+1}+Dy_{m+1} \implies 1 < (p+\sqrt{D}q)(x_{m}-\sqrt{D}y_{m}) = (px_{m}-Dqy_{m})+\sqrt{D}(qx_{m}-py_{m})< x_{0}+y_{0}sqrt{D}</math>. | + | <math>x_{m}+\sqrt{D}y_{m} < p+\sqrt{D}q < x_{m+1}+Dy_{m+1} \implies 1 < (p+\sqrt{D}q)(x_{m}-\sqrt{D}y_{m}) = (px_{m}-Dqy_{m})+\sqrt{D}(qx_{m}-py_{m})< x_{0}+y_{0}\sqrt{D}</math>. |
However, it can be seen that | However, it can be seen that |
Revision as of 11:56, 23 June 2018
A Pell equation is a type of diophantine equation in the form for a natural number . Generally, is taken to be square-free, since otherwise we can "absorb" the largest square factor into by setting .
Note that if is a perfect square, then this problem can be solved using difference of squares. We would have , from which we can use casework to quickly determine the solutions.
Alternatively, if D is a nonsquare then there are infinitely many distinct solutions to the pell equation. To prove this it must first be shown that there is a single solution to the pell equation.
Claim: If D is a positive integer that is not a perfect square, then the equation has a solution in positive integers.
Proof: Let be an integer greater than 1. We will show that there exists integers and such that with . Consider the sequence . By the pigeon hole principle it can be seen that there exists i, j, and p such that i < j, and
.
So we now have
.
We can now create a sequence of such that and which implies r and s. However we can see by the pigeon hole principle that there is another infinite sequence which will be denoted by such that . Once again, from the pigeon hole principle we can see that there exist integers f and g such that mod H, mod H, and . Define and notice that . Also note that mod H which means that Y = 0 mod H also. We can now see that is a nontrivial solution to pell's equation.
Family of solutions
Let be the minimal solution to the equation . Note that if are solutions to this equation then which means is another solution. From this we can guess that is obtained from . This does indeed generate all the solutions to this equation. Assume there was another solution . Then there exists some m such that
.
However, it can be seen that
Meaning is a solution smaller than the minimal solution which is a contradiction. This article is a stub. Help us out by expanding it.
Continued fractions
The solutions to the Pell equation when is not a perfect square are connected to the continued fraction expansion of . If is the period of the continued fraction and is the th convergent, all solutions to the Pell equation are in the form for positive integer .
Generalization
A Pell-like equation is a diophantine equation of the form , where is a natural number and is an integer.
Introductory Problems
Show that if and are the solutions to the equation , then .