(01-03-2014 08:39 PM)Thomas Klemm Wrote:  

(01-03-2014 05:38 PM)Bunuel66 Wrote:  This seems to show that having the equality is not enough for keeping it directly after integrating.

The problem I see is that \(u=-\frac{1}{x}\) is not defined for \(x=0\). The Taylor-series of \(\exp(u)\) is not defined for \(u=-\infty\).

Cheers
Thomas

(01-03-2014 08:03 PM)W_Max Wrote:  My pocket HP30b (yes, not wp34s ), using simplest rectangle method and step 0.00005 give 1.29128599414 after 3 minutes. Enjoy simple methods

(01-03-2014 09:04 PM)Bunuel66 Wrote:  Don't get the point, \(\exp(-\infty)\)=0.

(01-06-2014 10:28 AM)Thomas Klemm Wrote:  

(01-03-2014 09:04 PM)Bunuel66 Wrote:  Don't get the point, \(\exp(-\infty)\)=0.

The domain of \(\exp(x)\) is \(\mathbb{R}\), but \(-\infty \notin \mathbb{R}\). Thus you can not just plug \(-\infty\) into the Taylor-series of this function and expect everything works. You can calculate \(\lim_{x\to\infty}\exp(x)\) but that's not the same as \(\exp(-\infty)\). This expression is just not defined.

HTH
Thomas

(01-07-2014 06:12 PM)Bunuel66 Wrote:  Could have been rewriten as a limit to be more rigorous...;-)

• Change of order of double limit of function sequence
• When can you switch the order of limits?
• When can we exchange order of two limits?
  

(12-31-2013 01:14 PM)Thomas Klemm Wrote:  It takes 2'27" to calculate this integral on a DM-15CC with FIX 9.
It takes 28" to do it with the RPN-15C emulator on my iPhone.
On a real HP-15C it takes probably much longer.