The Diophantine Equation x2 + 2y2 = z2 (Part III)

A Method of Generating Triples from Novel Equations

This page is a method for generating triples of the form (x,y,z) for the Diophantine equation x2 + 2y2 = z2. The method is similar to a method employing imaginary numbers where the imaginary x is part of a magic square diagonal. In addition, the equations posted here differ in form from those in the magic square setting.

This new method is a way of producing triples from a set of novel equations that may be used to access the triples, x, y and z. The x, y and z as well as the equations are listed in the table headings below according to the following format:

δ1x y z δ2
a Da2 - n2 2na Da2 + n2

where a is a generating number starting at zero, the D is any integer greater than zero and the (n2, 2n) are values taken from table A:

Table A (n2 & 2n values)
n2149162536496481100...
2n2468101214161820...

Since there are an infinite number of (n2, 2n) integers there are also an infinite number of tables which can be tabulated with their accompanying equations. A second sequential access is also possible using the δ1 and δ2 columns whose δ1δ1 and δ2δ2 are both 4 for all the tables. In addition,the triples which are generated may be present in primitive or non primitive form, and these non primitives can be converted to primitive forms by dividing out any common factors.

Table I
δ1x y z δ2
a 2a2 - 1 2a 2a2 + 1
0-101
22
1123
66
2749
1010
317619
1414
431833
1818
5491051
2222
6711273
2626
7971499
Table II
δ1x y z δ2
a 2a2 - 4 4a 2a2 + 4
0-404
22
1-246
66
24812
1010
3141222
1414
4281636
1818
5462054
2222
6682476
2626
79828102

where Table IIA represents Table II after division by 2 where the as no longer match up and the δ1 and δ2 are no longer relevant.

Table IIA
x y z
-101
-123
123
7611
749
231027
17619
471451

Now for Tables III and IV.

Table III
δ1x y z δ2
a 2a2 - 9 6a 2a2 + 9
0-909
22
1-7611
66
2-11217
1010
391827
1414
4232441
1818
5413059
2222
6633681
2626
78942107
Table IV
δ1x y z δ2
a 2a2 - 16 8a 2a2 + 16
0-16016
22
1-14818
66
2-81624
1010
322434
1414
4163248
1818
5344066
2222
6564888
2626
78256114

For Tables V and VI.

Table V
δ1x y z δ2
a 2a2 - 25 10a 2a2 + 25
0-25025
22
1-231027
66
2-172033
1010
3-73043
1414
474057
1818
5255075
2222
6476097
2626
77370123
Table VI
δ1x y z δ2
a 2a2 - 36 12a 2a2 + 36
0-36036
22
1-341238
66
2-282444
1010
3-183654
1414
4-44868
1818
5146086
2222
63672108
2626
76084134

Finally we have Tables VII and VIII.

Table VII
δ1x y z δ2
a 2a2 - 49 14a 2a2 + 49
0-49049
22
1-471451
66
2-412857
1010
3-314267
1414
4-175681
1818
517099
2222
62384121
2626
74998147
Table VIII
δ1x y z δ2
a 2a2 - 64 16a 2a2 + 64
0-64064
22
1-621666
66
2-563272
1010
3-464882
1414
4-326496
1818
5-1480114
2222
6896136
2626
734112162

Only eight triples, (x,y,z), were used in the calculation for the Diophantine equation x2 + 2y2 = z2 to get an idea of its versatility. Note that the tables produced can be expanded downward indefinitely. In addition, using the tables one can generate the appropriate equations that are useful for generating any triple in a table using a random access method or using δ1 and δ2 to access the (x,y,z)s sequentially.

This concludes Part III. Go back to Part II. Go to Part IV.

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Copyright © 2020 by Eddie N Gutierrez. E-Mail: enaguti1949@gmail.com