Difference between revisions of "Pell's equation (simple solutions)"
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Therefore numbers <cmath>y_i = \frac {F_{4i} + F_{4i – 2} + 1}{5}</cmath> are integer. | Therefore numbers <cmath>y_i = \frac {F_{4i} + F_{4i – 2} + 1}{5}</cmath> are integer. | ||
− | We using < | + | We using <cmath>F_{2i-1}^2- F_{2i} \cdot F_{2i-2} = 1, F_{4i} = F_{2i} (F_{2i+1} + F_{2i-1}), |
− | + | F_{4i – 2} = F_{2i-1}(2F_{2i} - F_{2i-1})</cmath> and get <cmath>y_i = F_{2i} F_{2i-1}.</cmath> | |
− | We using < | + | We using <cmath>F_{4i-1}= F_{2i}^2 + F_{2i-1}^2, F_{2i-1}^2 - F_{2i} \cdot F{2i-2} = 1,</cmath> |
and get | and get | ||
− | < | + | <cmath>x_i = \frac{ 3y_i - 1 + F_{4i-1}}{2} = \frac{ F_{2i}(3F_{2i-1} + F_{2i} +F_{2i-2})}{2} = F_{2i} \cdot F_{2i+1}.</cmath> |
− | <cmath>\[ | + | <cmath>\begin{array}{c|c|c|c|c|c|c|c} |
− | + | & & & & & & & \\ [-2ex] | |
− | + | \boldsymbol{i} & 1 & 2 & 3 & 4 & 5 & 6 & 7 \\ [0.5ex] \hline | |
− | + | & & & & & & & \\ [-1.5ex] | |
− | + | \boldsymbol{u_i} & 1 & 4 & 11 & 29 & 76 & 199 & 521 \\ [1ex] | |
− | + | \boldsymbol{v_i} & 1 & 2 & 5 & 13 & 34 & 89 & 233 \\ [1ex] | |
+ | \boldsymbol{x_i} & 2 & 15 & 104 & 714 & 4895 & 33552 & 229970 \\ [1ex] | ||
+ | \boldsymbol{y_i} & 1 & 6 & 40 & 273 & 1870 & 12816 & 87841 \\ [1ex] | ||
+ | \end{array}</cmath> | ||
Revision as of 17:27, 19 April 2023
Pell's equation is any Diophantine equation of the form where is a given positive nonsquare integer, and integer solutions are sought for and
Denote the sequence of solutions It is clear that
During the solution we need:
a) to construct a recurrent sequence or two sequences
b) to prove that the equation has no other integer solutions.
Contents
Equation of the form
Prove that all positive integer solutions of the equation can be found using recursively transformation of the pare
Proof
Let integers are the solution of the equation Then
Therefore integers are the solution of the given equation. If then
Suppose that the pare of the positive integers is the solution different from founded in
Let then therefore integers are the solution of the given equation.
Similarly
There is no integer solution if is impossible. So
There is no member in the sequence hence it is infinitely decreasing sequence of natural numbers. There is no such sequence. Contradiction.
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Equation of the form
Prove that all positive integer solutions of the equation can be found using recursively transformation of the pare In another form
Proof
It is the form of Pell's equation, therefore
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Equation of the form
Prove that all positive integer solutions of the equation can be found using recursively transformation of the pare
Proof
Similarly as for equation
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Pythagorean triangles with almost equal legs
Find all triangles with integer sides one leg of which is more than the other.
Find all natural solutions of the equation
Solution
All positive integer solutions of the equation can be found using recursively transformation of the pare
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Equation of the form
Prove that the equation have not any solution.
Proof
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Equation of the form
Prove that all positive integer solutions of the equation can be found using recursively transformation of the pares and .
Proof
Let integers are the solution of the equation Then
Therefore integers are the solution of the given equation. The pare of the positive integers is the solution different from founded in
Let then therefore integers are the solution of the given equation.
Similarly
If then
There is no member in the sequence hence it is infinitely decreasing sequence of natural numbers. There is no such sequence. Contradiction.
We need to check (no solution), but gives the integer solution, so there is the second sequence of the integer solutions vladimir.shelomovskii@gmail.com, vvsss
Equation of the form
Prove that all positive integer solutions of the equation are They can be found using recursively transformation of the pares
Proof Let the pare of the positive integers be the solution of given equation and Then
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Equation of the form
Prove that all positive integer solutions of the equation are They can be found using recursively transformation of the pares
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Equation for binomial coefficients
Find all positive integer solutions of equation
Solution It is known that every real quadratic form under a linear change of variables may be transformed in a "diagonal form". where L is Lucas number, It is clear that The sequence of Lucas numbers modulo 5 is periodic, the period is 4, and the numbers with index 4i-1 are 4 modulo 5.
Therefore numbers are integer.
We using and get
We using and get
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Equation of the form
Prove that all positive integer solutions of the equation are It is clear that solutions can be found using recursively transformation of the pare
One can use the small transform for understanding
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