Saturday, November 19, 2022

Casio fx-9750GIII: Integrals with Infinite Limits

Casio fx-9750GIII:  Integrals with Infinite Limits





A Substitution to Get to Infinity... 


It is quite a challenge to calculate numerical integrals with infinite limits such as 


∫( f(x) dx, a, ∞)


∫( f(x) dx, -∞, a)


∫( f(x) dx, -∞, ∞)



A trick is to substitute x = tan Θ.  Then:


Θ = arctan x


dx = sec^2 Θ dΘ = cos^-2 Θ dΘ



Note that


lim t→∞ arctan t = π/2


lim t→-∞ arctan t = -π/2  


In this blog, assume that radian angle mode is used in all calculations.


Let's go over some examples and see how it works.  I used a Casio fx-9750GIII, however, this technique should work with all calculators with numerical integral calculations.  Furthermore, changing the integral will allow for Simpson's Rule or Trapezoid Rule approximation.


For the upper limit, I approximate π/2.


A = 1.5708  (π/2 to 4 places)

B = 1.570796  (π/2 to 6 places)

C = 1.57079633 (π/2 to 8 places)



Example 1:  


∫( e^(-x^2) dx, 0, ∞)  


transforms to


∫( e^(-tan^2 Θ)/cos^2 Θ dΘ, 0, ≈π/2)


Calculations (fx-9750GIII):


Upper Limit: A (see above),  Result:  0.8862269255


Upper Limit: B,  Result:  0.8862269255


Upper Limit: C,  Result:  0.8862269255




Example 2:  


∫(x^0.5 * e^(-x) dx, 0, ∞)


transforms to


∫((tan Θ)^0.5 * e^(-tan Θ))/cos^2 Θ dΘ, 0, π/2)


Calculations:


Upper limits A, B, C:  0.862269255


Coincidently, ∫( e^(-x^2) dx, 0, ∞)  = ∫(x^0.5 * e^(-x) dx, 0, ∞) = Γ(1.5) = √(π)/2




Example 3:


∫( e^x*(x^2 + 1) dx, -∞, 0)


transforms to


∫( e^(tan Θ) * (tan^2 Θ + 1)/cos^2 Θ dΘ, -π/2, 0)

=  ∫( e^(tan Θ) * 1/cos^2 Θ * 1/cos^2 Θ dΘ, -π/2, 0)

∫( e^(tan Θ)/cos^4 Θ dΘ, -π/2, 0)


For upper limits A, B, C, the answer returned is 3, which is the exact answer.  


For integrals like this all is needed is a four digit approximation of π/2 = 1.5708.



Let's keep going:


Example 4:


∫( (x^2 + 1)/(x^4 - 1) dx, 0, ∞) 


transforms to


∫( 1/cos^Θ * (tan^2 Θ + 1)/(tan^4 Θ - 1) dΘ, 0, π/2)

= ∫( 1/(sin^4 Θ - cos^4 Θ) dΘ, 0, π/2)


On the fx-9750GIII get MA Error.  



Example 5:


∫( 1/√(x^2 + 3*x + 1) dx, 0, ∞)


transforms to 


∫( 1/(cos^2 Θ * √(tan^2 Θ + 3 * tan Θ + 1)) dΘ, 0, π/2)


like example 4, I get the MA Error.



Observation:  the transformation works best if the integral involves some form of either of the following:


f(x) * e^(g(x))


or 


f(x) * e^(-g(x))



Gamma


The Gamma Function is an excellent candidate for this transformation.  


Γ(t) = ∫( x^(t-1) * e^-x dx, 0, ∞)


transforms to


∫( tan^(t-1) Θ * e^(-tan Θ)/cos^2 Θ dΘ, 0, π/2)



Source


Mier-Jedrzejuwicz, W.A.C. Ph.D.    Tips And Programs for the HP 32S   Synthetix Publication.  Berkeley, CA.  September 1988.  ISBN 0-937637-05-X


Download the book here:  https://literature.hpcalc.org/items/1756




Happy calculating,


Eddie


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