The Beal’s Conjecture, Catalan’s Theorem and Fermat’s Last Theorem are cases within the number theory’s field, so the Beal’s Conjecture states that: AX+BY=CZ where A, B, C are positive integers and X, Y and Z are all positive integers greater 2, then A, B and C have a common prime factor and Catalan’s Theorem express that Yp=Xq+1 when X, Y, q, p are integer numbers and greater than one, this equation has not solution in integer numbers exception to 8, 9 numbers. The Fermat’s Last Theorem has the form of the Beal’s Conjecture when X, Y, and Z equal to n, then states that impossible find any solution in integer numbers for this equation. This article presents the proof of the Beal, Catalan and Fermat’s Last Theorem, and generalizes these theorems have relationship with arithmetic sequence that this sequence outcome from subtraction of exponent integer numbers between successive terms. Then illustrated an exponent integer numbers built from two parts: one of the progression and other the non-progression, when a Diophantine equation has square power we dealt with summation of one series of arithmetic sequence that can increase terms of a progression by other progression. Thus can find relationship between Pythagoras’ equation, Catalan and Fermat-Catalan’s equation that obtained from Pythagoras’ equation (a2+b2=c2), the other word Catalan and Fermat-Catalan’s equation a form of Pythagoras’ equation when displace a point on the circle, at that time Pythagoras’ equation reform to Catalan and Fermat-Catalan’s equation. And also the Beal’s Conjecture when A, B, C are coprime, another form of Fermat’s Last Theorem that both dealt with summation of several series of arithmetic progression, that impossible increase terms of a progression by other progression or a several series of sequence that shape is similar to a triangular that represented rows of progression and with a non-sequence parts that must change to sequences which rows of this progression less than initial progression. Also determine the Fermat’s Last Theorem has no solution in integer number then Beal’s Conjecture when A, B, C are coprime also has no solution in integer number. The last term provides rules of Beal’s Conjecture for solution and determine that this conjecture is super circles that obtained from primary circles, this primary circles existed from Catalan’s Theorem, Fermat-Catalan’s theorem and other forms. All of primary circles are based on the Pythagoras’ equation and right triangle.
Published in | Pure and Applied Mathematics Journal (Volume 11, Issue 4) |
DOI | 10.11648/j.pamj.20221104.12 |
Page(s) | 51-69 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2022. Published by Science Publishing Group |
Beal’s Conjecture, Catalan’s Theorem, Fermat’s Last Theorem, Pythagoras’ Equation, Arithmetic Progression, Prime Numbers, Integer Numbers
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APA Style
Mohammad Amin Sharifi. (2022). Proof of the Beal, Catalan and Fermat’s Last Theorem Based on Arithmetic Progression. Pure and Applied Mathematics Journal, 11(4), 51-69. https://doi.org/10.11648/j.pamj.20221104.12
ACS Style
Mohammad Amin Sharifi. Proof of the Beal, Catalan and Fermat’s Last Theorem Based on Arithmetic Progression. Pure Appl. Math. J. 2022, 11(4), 51-69. doi: 10.11648/j.pamj.20221104.12
@article{10.11648/j.pamj.20221104.12, author = {Mohammad Amin Sharifi}, title = {Proof of the Beal, Catalan and Fermat’s Last Theorem Based on Arithmetic Progression}, journal = {Pure and Applied Mathematics Journal}, volume = {11}, number = {4}, pages = {51-69}, doi = {10.11648/j.pamj.20221104.12}, url = {https://doi.org/10.11648/j.pamj.20221104.12}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.pamj.20221104.12}, abstract = {The Beal’s Conjecture, Catalan’s Theorem and Fermat’s Last Theorem are cases within the number theory’s field, so the Beal’s Conjecture states that: AX+BY=CZ where A, B, C are positive integers and X, Y and Z are all positive integers greater 2, then A, B and C have a common prime factor and Catalan’s Theorem express that Yp=Xq+1 when X, Y, q, p are integer numbers and greater than one, this equation has not solution in integer numbers exception to 8, 9 numbers. The Fermat’s Last Theorem has the form of the Beal’s Conjecture when X, Y, and Z equal to n, then states that impossible find any solution in integer numbers for this equation. This article presents the proof of the Beal, Catalan and Fermat’s Last Theorem, and generalizes these theorems have relationship with arithmetic sequence that this sequence outcome from subtraction of exponent integer numbers between successive terms. Then illustrated an exponent integer numbers built from two parts: one of the progression and other the non-progression, when a Diophantine equation has square power we dealt with summation of one series of arithmetic sequence that can increase terms of a progression by other progression. Thus can find relationship between Pythagoras’ equation, Catalan and Fermat-Catalan’s equation that obtained from Pythagoras’ equation (a2+b2=c2), the other word Catalan and Fermat-Catalan’s equation a form of Pythagoras’ equation when displace a point on the circle, at that time Pythagoras’ equation reform to Catalan and Fermat-Catalan’s equation. And also the Beal’s Conjecture when A, B, C are coprime, another form of Fermat’s Last Theorem that both dealt with summation of several series of arithmetic progression, that impossible increase terms of a progression by other progression or a several series of sequence that shape is similar to a triangular that represented rows of progression and with a non-sequence parts that must change to sequences which rows of this progression less than initial progression. Also determine the Fermat’s Last Theorem has no solution in integer number then Beal’s Conjecture when A, B, C are coprime also has no solution in integer number. The last term provides rules of Beal’s Conjecture for solution and determine that this conjecture is super circles that obtained from primary circles, this primary circles existed from Catalan’s Theorem, Fermat-Catalan’s theorem and other forms. All of primary circles are based on the Pythagoras’ equation and right triangle.}, year = {2022} }
TY - JOUR T1 - Proof of the Beal, Catalan and Fermat’s Last Theorem Based on Arithmetic Progression AU - Mohammad Amin Sharifi Y1 - 2022/07/26 PY - 2022 N1 - https://doi.org/10.11648/j.pamj.20221104.12 DO - 10.11648/j.pamj.20221104.12 T2 - Pure and Applied Mathematics Journal JF - Pure and Applied Mathematics Journal JO - Pure and Applied Mathematics Journal SP - 51 EP - 69 PB - Science Publishing Group SN - 2326-9812 UR - https://doi.org/10.11648/j.pamj.20221104.12 AB - The Beal’s Conjecture, Catalan’s Theorem and Fermat’s Last Theorem are cases within the number theory’s field, so the Beal’s Conjecture states that: AX+BY=CZ where A, B, C are positive integers and X, Y and Z are all positive integers greater 2, then A, B and C have a common prime factor and Catalan’s Theorem express that Yp=Xq+1 when X, Y, q, p are integer numbers and greater than one, this equation has not solution in integer numbers exception to 8, 9 numbers. The Fermat’s Last Theorem has the form of the Beal’s Conjecture when X, Y, and Z equal to n, then states that impossible find any solution in integer numbers for this equation. This article presents the proof of the Beal, Catalan and Fermat’s Last Theorem, and generalizes these theorems have relationship with arithmetic sequence that this sequence outcome from subtraction of exponent integer numbers between successive terms. Then illustrated an exponent integer numbers built from two parts: one of the progression and other the non-progression, when a Diophantine equation has square power we dealt with summation of one series of arithmetic sequence that can increase terms of a progression by other progression. Thus can find relationship between Pythagoras’ equation, Catalan and Fermat-Catalan’s equation that obtained from Pythagoras’ equation (a2+b2=c2), the other word Catalan and Fermat-Catalan’s equation a form of Pythagoras’ equation when displace a point on the circle, at that time Pythagoras’ equation reform to Catalan and Fermat-Catalan’s equation. And also the Beal’s Conjecture when A, B, C are coprime, another form of Fermat’s Last Theorem that both dealt with summation of several series of arithmetic progression, that impossible increase terms of a progression by other progression or a several series of sequence that shape is similar to a triangular that represented rows of progression and with a non-sequence parts that must change to sequences which rows of this progression less than initial progression. Also determine the Fermat’s Last Theorem has no solution in integer number then Beal’s Conjecture when A, B, C are coprime also has no solution in integer number. The last term provides rules of Beal’s Conjecture for solution and determine that this conjecture is super circles that obtained from primary circles, this primary circles existed from Catalan’s Theorem, Fermat-Catalan’s theorem and other forms. All of primary circles are based on the Pythagoras’ equation and right triangle. VL - 11 IS - 4 ER -