HP35s and numerical differentiation
10-05-2014, 10:58 AM
Post: #1
 mcjtom Member Posts: 70 Joined: Jul 2014
HP35s and numerical differentiation
What would be the simplest way of estimating a slope of tangent to function/expression (say, already stored in equation library) for a specified variable at a specified point?

I imagine I could write a programme that would use, say, two-point secant formula (or some higher precision formulas), but how would I parse a function from an equation library to it? Is there a simpler way?
10-05-2014, 11:47 AM
Post: #2
 Dieter Senior Member Posts: 2,397 Joined: Dec 2013
RE: HP35s and numerical differentiation
(10-05-2014 10:58 AM)mcjtom Wrote:  What would be the simplest way of estimating a slope of tangent to function/expression (say, already stored in equation library) for a specified variable at a specified point?

There are several ways of evaluating the derivative of a function, a quite elegant one is shown below.

Quote:I imagine I could write a programme that would use, say, two-point secant formula (or some higher precision formulas), but how would I parse a function from an equation library to it? Is there a simpler way?

There is no way to access the equation list from within a user program. Sorry.

However, if the original function is defined in user code, another program may determine the derivative. A quite elegant way uses the 35s' complex mode. This has been discussed earlier in the old forum. A discussion with a working example in a 35s program can be found in this thread. Label F defines the function, label D calculates the derivative.

When entering the function F, be sure to use only commands the 35s can handle in complex mode, e.g. use x^ 0.5 instead of sqrt(x).

Dieter
10-05-2014, 04:43 PM
Post: #3 Eddie W. Shore Senior Member Posts: 1,290 Joined: Dec 2013
RE: HP35s and numerical differentiation
In addition to the user programs suggested, here is one that calculates the numerical derivate, using the Five Stencil Method.

Use the label U, the function is called at step 41.

Code:
 U001 LBL U U002 1E-3 U003 STO H U004 2 U005 x U006 R-down U007 STO Z U008 R-up U009 + U010 STO X U011 XEQ U041 U012 +/- U013 STO D U014 RCL Z U015 RCL+ H U016 STO X U017 XEQ U041 U018 8  U019 x U020 STO+ D U021 RCL Z U022 RCL- H U023 STO X U024 XEQ U041 U025 8 U026 x U027 STO- D U028 RCL Z U029 RCL H U030 2 U031 x U032 - U033 STO X U034 XEQ U041 U035 STO+ D U036 12 U037 RCLx H U038 STO/ D U039 VIEW D   // derivative U040 RTN U041  *** put f(X) **** here ... U-last RTN

f'(X) = D = 1/(12H) * ( f(x-2H) - 8*f(x-H) + 8*f(x+H) - f(x+2H)) + H^4/30*f^(5)(o)
(error term omitted in calculation)

Source:
Burden, Richard L. and J. Douglas Faires. "Numerical Analysis 8th Edition" Thomson Brooks/Cole. Belton, CA 2005
10-05-2014, 09:39 PM
Post: #4
 Thomas Klemm Senior Member Posts: 1,548 Joined: Dec 2013
RE: HP35s and numerical differentiation
(10-05-2014 04:43 PM)Eddie W. Shore Wrote:  $\frac{f(x-2h)-8f(x-h)+8f(x+h)-f(x+2h)}{12h}$

This expression can be transformed into:
$\frac{4\frac{f(x+h)-f(x-h)}{2\cdot h}-\frac{f(x+2h)-f(x-2h)}{2\cdot 2h}}{4-1}$

Now we can see that this is the 1st step of the Richardson extrapolation for $$\frac{f(x+h)-f(x-h)}{2\cdot h}$$: This can be extended similar to Romberg's method.

Cheers
Thomas
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