TABLEAU RADIAL PIE GAUGE CHART TUTORIAL
How to Create a Spirallic Numbers Dataset
Make the dataset by opening a new Excel worksheet and choosing a cell inwards and downwards about 10 rows and columns to start inputting the numbers into.You may start with 0 or 1 or any number; 1 is recommended.
Proceed sequentially outwards in a spiral.If you want to save a little time, use a formula like "=J15+1" and copy it up, across or down off as many cells as need be. You may then find a like formula nearby as you go outwards, which will speed things up greatly. This will also allow you to use any originating number in the center, should you so choose..
After you have built the data set up to 100 or 324 (as in the example), you're good to go!
You will notice right away that the prime numbers are fairly evenly distributed in the 4 quadrants at this point.You might try blocking in non-primes in groups in patterns to see if you can predict primes!
Notice there are a number of sequences to the columns and numbers which follow Summation Notation.
Notice also that the first sequence is easy -- it's the diagonal from the center to the bottom right.Its pattern to produce the sequence 1,3,13,31,57,91,133,183,241,307, ... is -1*0+1=1, 1*2+1=3, 3*4+1 =13, 5*6+1 = 31, etc. You will find a similar pattern extending to the upper left.
- Notice that the second pattern is trickier: the vertical pattern that produces the sequence 1,4,15,34,61,96,139,190,249,316 is more involved. If one takes the difference of those numbers and then the differences of the differences, one gets 8's, so one knows that a constant value of 8 is being added in the sequence. Knowing that, a typical rate of change is produced by ((a*b)+c)+8 = result, with a being constant. Such is the case here as it turns out, for the sequence is produced by ((4*-2)+4+8)=4, ((4*1)+3+8)=15, ((4*6)+2+8)=34, ((4*13)+1+8) = 61, etc. with the increment to b being 3,5,7,... and the increment to c being -1, while a=4 and 8 are constants. There's an elegant way to write that in Summation Notation with N's and K's and i's and all but it's beyond the text capacity we're operating under. Actually, I just found another way to resolve the series: 1==((-1*0)-7)+8, 4=((1*2)-6)+8, 15=((3*4)-5)+8, 34=((5*6)-4)+8, 61=((7*8)-3)+8, 96=((9*10)-2)+8, etc.
Notice the horizontal pattern is a bit trickier to discover.8's were again a constant difference of the differences but it took me awhile to find the rest of the formula. The sequence of 11,28,53,86,127,176,233,298, ... is generated as far as I know by ((4*-5)+23)+8=11, ((4*-1)+24)+8 = 28, ((4*5)+25)+8 = 53, ((4*13)+26)+8 = 86, etc., with a=4 and 8 remaining constant while b increments by 4, 6, 8,... and c incrementing by 1. Again, there's a more elegant way to state that. If anyone happening to read this can help out, great. There's another way to resolve this sequence also: 2=((2*3)-12)+8, 11=((4*5)-17)+8, 28=((6*7)-22)+8, 53=((8*9)-27)+8, 86=((10*11)-32)+8, 127=((12*13)-37)+8, 176=((14*15)-42)+8, 233=((16*17)-47)+8, and 298 =((18*19)-52)+8, etc. with element c decrementing by -5 each time.
Notice that the diagonals take the form of ((a*b)+c)+d = Sum wherein b_sub_0 is 1 greater than a_sub_zero, a_sub_1 was 2 greater than a_sub_0 and b_sub_1 was 2 greater than b_sub_0, i.e.(1*2) changed next to (3*4). This might be the general pattern instead of working with 4's as had been, The role of d=8, the difference of the differences, was still present, so then you just need to figure out which a and b pair best approximated the answer and adjust with c accordingly, by trial and error. It did not take long to hit upon the solutions.
There are resolved 2 more sequences:5=((2*3)-9)+8, 18=((4*5)-10)+8, 39=((6*7)-11)+8, etc. and also 8==((2*3)-6)+8, 23=((4*5)-5)+8, 46=((6*7)-4)+8, 77=((8*9)-3)+8, 116=((10*11)-2)+8,163=((12*13)-1)+8, 218=((14*15)-0)+8 and 281=((16*17)+1)+8. These were done by the analytical method described above in Step 9, though it's a good hunch the problem will only yield to greater finesse than the lazy mathematician possesses.
Explanatory Charts, Diagrams, Photos
Review the spirallic dataset again to see if you can spot any other sequences in it -- how about the Fibonacci Series?Has anyone hi-lited that yet? Might be interesting! #
Make use of helper articles when proceeding through this tutorial:
- See the article How to Datamine for Primes Using a Spirallic Dataset for a list of articles related to Excel, Geometric and/or Trigonometric Art, Charting/Diagramming and Algebraic Formulation.
- For more art charts and graphs, you might also want to click on Category:Microsoft Excel Imagery, Category:Mathematics, Category:Spreadsheets or Category:Graphics to view many Excel worksheets and charts where Trigonometry, Geometry and Calculus have been turned into Art, or simply click on the category as appears in the upper right white portion of this page, or at the bottom left of the page.
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- Nature uses spirals in building all sorts of forms, from organs to the abdomens of wasps, etc. -- all the way down to the stinger I imagine! That's the information I have from a Father (Priest) who lectured on Nature at a local college; I do not know so from firsthand microscopic observation however.
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Date: 05.12.2018, 01:50 / Views: 32563