The Diophantine Equation x2 + D(y2 + z2) = w2 (Part VI)

A Method for Generating Quadruples from Novel Equations

This is a continuation of Part V, a method for generating Diophantine quadruples of the form (x,y,z,w) for the Diophantine equation x2 + D(y2 + z2) = w2. The new method produces quadruples from a set of novel equations. The x, y,z and w variables as well as the equations used are listed in the headings of table A using the following format:

Table A
δ1x y zw δ2
ab D(a2 + b2) - n2 2na2nb D(a2 + b2) + n2

where a and b are generating numbers, D is the coefficient of a2 and b2 whose value is any number greater than zero and the (n2, 2n) are values taken from the following table:

Table B (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. Access can be either thru the equations or via the use of the δ1 and δ2 columns. In addition,the quadruples 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.

The values for (x,y,z,w) are actually variables which can be used in the Diophantine equation x2 ± D(y2 + z2) = w2. Furthermore, since the + and − forms of this equation give identical entries in the tables (z columns are swapped with the w columns), only the + equation will be used with the numbers generated in the tables. In addition, the generating function a is equal to 2 for the tables in this section.

To start Table XXI D is set to 1 and the value of n from Table B above is set to 3.

Table XXI (D = 1, n = 3)
δ1x y zw δ2
ab D(a2 + b2) - n2 2na2nb D(a2 + b2) + n2
21−412614
33
22−1121217
55
234121822
77
2411122429

Table XXI contains two primitive and two non primitive forms. The non primitive forms (rows 1 and 5) after division by common factors give the Diophantine quadruples (−2,3,6,7) and (2,6,9,11) which when plugged into the equation x2 + D(y2 + z2) = w2 gives:

4 + 1(9 + 36) = 49
4 + 1(36 + 81) = 121

All these D = 1 quadruples exhibit the property of being both Pythagorean as well as Diophantine. These quadruples not only are known in the literature but have been generated via similar methods shown here. On the other hand, the Diophantine quadruples with D greater than one may not be. Table XXII gives the various values when D = 2.

Table XXII (D = 2, n = 3)
δ1x y zw δ2
ab D(a2 + b2) - n2 2na2nb D(a2 + b2) + n2
21112619
66
227121225
1010
2317121835
1414
2431122449

Every row is this table consists of primitive quadruples.

The next two tables XXIII where D = 3 and XXIV where D = 4 are depicted below:

Table XXIII (D = 3, n = 3)
δ1x y zw δ2
ab D(a2 + b2) - n2 2na2nb D(a2 + b2) + n2
21612624
99
2215121233
1533
2330121848
2121
2451122469

Squaring and substituting these values into x2 + 3(y2 + z2) = w2 confirms w.

Table XXIV (D = 4, n = 3)
δ1x y zw δ2
ab D(a2 + b2) - n2 2na2nb D(a2 + b2) + n2
211112629
1212
2223121241
2020
2343121861
2828
2471122489

All the rows are non primitive. Squaring and substituting the values from this table into x2 + 4(y2 + z2) = w2 confirms w.

This concludes Part VI.

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