Login

Gottfried · (This post was last modified: 10/14/2007, 07:46 PM by Gottfried.)

The matrix, analytically constructed based on the hypothese, that the eigenvalues are the consecutive powers of u = log(t)

$\hspace{24} \begin{matrix} {rrr} 1.00000000000 & 1.00000000000 & 1.00000000000 \\ 0 & 1.57079632679*I & 3.14159265359*I \\ 0 & -1.23370055014 & -4.93480220054 \\ 0 & -0.645964097506*I & -5.16771278005*I \\ 0 & 0.253669507901 & 4.05871212642 \\ 0 & 0.0796926262462*I & 2.55016403988*I \\ 0 & -0.0208634807634 & -1.33526276886-2.13383011501E-12*I \\ 0 & -0.00468175413532*I & 9.74997503272E-12-0.599264529316*I \\ 0 & 0.000919260274839 & 0.235330630320+1.03824464497E-11*I \\ 0 & 0.000160441184787*I & 7.34062412572E-11+0.0821458865076*I \\ 0 & -0.0000252020423730 & -0.0258068913636+0.000000000336008212438*I \\ 0 & -0.00000359884323522*I & -0.000000000531166859357-0.00737043148889*I \\ 0 & 0.000000471087478009 & 0.00192957576096+1.44905471842E-10*I \\ 0 & 0.0000000569217294451*I & -0.00000000197293927481+0.000466304152891*I \\ 0 & -0.00000000638660319694 & -0.000104637211800-0.00000000321239246183*I \\ 0 & -0.000000000668803312296*I & 0.00000000165543902983-0.0000219117619420*I \\ 0 & 6.56592442263E-11 & 0.00000429946860414-0.00000000166180488357*I \\ 0 & 6.06668588155E-12*I & 0.00000000320792169496+0.000000794286619384*I \\ 0 & -1.00000000000E-12 & -0.000000140053803989+0.00000000195676397990*I \\ 0 & 0 & -2.05225455659E-10-0.0000000242612901612*I \\ 0 & 0 & 0.00000000407962123588+0.000000000376346155829*I \\ 0 & 0 & -2.13051400732E-10+0.000000000561705712732*I \\ 0 & 0 & -4.37085349142E-11-4.53336927688E-11*I \\ 0 & 0 & 3.32471067492E-12-1.00000000000E-12*I \end{matrix}$

(the second column are the interesting ones, they serve as coefficients for the powerseries in x for the expression {I,x}^^I ), and if x=1 they simply must be summed )

And the partial-sums of the second column should converge to y=I, since this means y = {I,1}^^I, :

$\hspace{24} \begin{matrix} {rrr} 0.977995110024+0.146699266504*I \\ 0.570308500749+1.47507813506*I \\ -0.114402540375+1.14713275303*I \\ -0.0106044591818+0.993956473385*I \\ -0.00229741633360+1.00160960663*I \\ -0.000143765522959+0.999877073257*I \\ -0.0000575116782223+1.00002476990*I \\ -0.000000580602181001+1.00000205224*I \\ -0.00000100453146370+1.00000024808*I \\ -0.00000000833987995204+1.00000016631*I \\ 0.00000000258190521640+1.00000000353*I \\ -0.000000000512676097081+1.00000000285*I \\ 0.000000000486292953022+1.00000000023*I \\ 2.59309575160E-11+0.999999999974*I \\ 4.18678540668E-12+1.00000000000*I \\ 1.17217031429E-12+0.999999999999*I \\ 1.00000000000*I \\ 1.00000000000*I \\ 1.00000000000*I \\ 1.00000000000*I \\ 1.00000000000*I \\ 1.00000000000*I \\ 1.00000000000*I \\ 1.00000000000*I \end{matrix}$

This is also good for integer powers of this matrix; but again, for fractional or even complex powers the obtainable results for this parameters with that number of terms (24(last document) or 32) are not convincing.

Gottfried

Matt D · 10/15/2007, 04:52 PM

Wow, thanks everyone! --- just give me a second to digest it all...

Login
Username:
Password:	Lost Password?
	Remember me

Possibly Related Threads...
Thread		Author	Replies	Views	Last Post
	Superroots and a generalization for the Lambert-W	Gottfried	22	36,371	12/30/2015, 09:49 AM Last Post: andydude