Expansions and techiques of integration
Authors:  Bill Davis, Horacio Porta and Jerry Uhl  < STRONG>©1999
Producer:  Bruce Carpenter
Publisher:         Distr ibutor:  

3.Approximation

3.01 Splines

Mathematics.

Remarkable plots explained by order of contact.  Splining for smoothness at the knots.

Science and math experience.

Experiments geared at discovering that the smoother the transition from one curve to another at a knot, the better both curves approximate each other near the knot.  Splining functions and polynomials.  Splines in road design.  Landing an airplane. &nbs p;The natural cubic spline.  Order of contact for derivatives and integrals.

3.02 Expansions in Powers of x

Mathematics.

The expansion of a function  in powers of  as a file of polynomials  with higher and higher orders of contact with  at .  The expansions every literate calculus person knows:       , , , and .
Converting known expansions to others via change of variable.
Expansions for approximations.

Science and math experience.

Experiments geared toward discovering that using more and more of the  expansion results in better and better approximation. &nbs p;Halley's way of  calculating accurate decimals of .  Expansions by substitution.  Expansions by differentiation.   ;Expansions by integration.  Recognition of  expansions.  Expansions that satisfy a priori error bounds.

3.03 Using Expansions

Mathematics.

The expansion of a function  in powers of  as a file of  polynomials with higher and higher orders of contact with  at .  Netwon's method.  Multiplying and di viding expansions.  Using expansions to help calculate limits at a point.  Expansions and the complex exponential function.& nbsp; Using expansions to help to get precise estimates of some integrals.

Science and math experience.

Centering expansions for good approximation.  Newton's method for root finding.  Successes and failures of Newton's method.& nbsp; Using the complex exponential to generate trigonometric identities.  Comparing reflecting properties of spherical mirrors and the reflecting properties of parabolic mirrors.  Using expansions to see why spherical mirrors have limited ability to concentrate light rays.  Behavior of expansions very close to .  Behavior of expansions far away from .

3.04 Taylor's Formula
    

Mathematics.

Taylor's formula for expansions in powers of .

Science and math experience.

Euler, Midpoint and Runge-Kutta approximations of  given .   Experiments comparing the quality of Midpoint and Runge-Kutta approximations.  A daption of Euler, Midpoint and Runge-Kutta approximations to approximating the plots of the differential equation , with  given.  Taylor's formula in rever se. L'Hospital's rule by dividing the leading term of the expansion of the denominator into the leading term of the expansion of the numerator. Centering the expansion for best approximation.  Experiments comparing the derivative of the expansion and the expansion of   ;the derivative.

3.05 Barriers to Convergence

Mathematics.

Barriers and complex singularities.  The convergence interval of an expansion as the interval between the barriers.  Why som e functions such as  have convergence barriers and others such as  and  do not.  Why functions such as  and  do not have expansions in powers of  but do have expansions in powers of  for .  Why the convergence in tervals for ,  and are the same.

Science and math experience.

Shortcuts based on the expansion of in powers of .  Using the expansion of  in powers of  for drug dosing.  Infinite sums of numbers resulting from expansions. Barriers resulting from splines. Infinite sums and decimals.  Experiments relating expansions in powers of  to interpolating polynomials.  Rung e's disaster.

3.06 Power Series

Mathematics.

Functions defined by a power series.  Functions defined by power series via differential equations.  The power series conver gence principle, which says that if for some positive number  the infinite list
       
is bounded , then the power series       
converges for .

Science and math experience.

Experiments in trying to plot functions defined by power series.  Experiments in plotting a function defined by a power series via a&n bsp; differential equation versus plotting the same function directly through  Mathematica's numerical differential equati on solver. The ratio test for  power series as a consequence of the power series convergence principle.
The  functions , and  from the viewpoint of power series. Experiments in truncation of power series.  The Airy function as a function defined by a power series.

2.04 Transforming Integrals
  

Mathematics.

Using the chain rule and the fundamental formula to see why 
         
and using this fact to transform one integral into another.  Measuring area under curves given parametrically.  Bell shaped curves and Gauss's normal probab ility law; mean and standard deviation.

Science and math experience.

Study of the error function, . Using tranformations to explain Mathematica output. Polar plots and area measurements. Using transformations to expla in the meaning of standard deviation in Gauss's normal law. Expected life of light bulbs and how long to set the guarantee on them. Using Gauss' s normal law to help to program coin-operated coffee machines. IQ test results. Using Gauss's normal law to organize SAT scores into quartiles a nd deciles. Comparison of 1967 and 1987 SAT scores. "Grading on the curve."

2.05 2D integrals and the Gauss-Green Formula

Mathematics.

Meaning of the plot of . The 2D integral 
         
as a volume measurement via slicing and acculumulating.  Gauss-Green formula (Green's theorem) as a way of calculating a double integral numerically as a single integral.

Science and math experience.

Volume and area measurements with 2D integrals. Area and volume measurements via the Gauss-Green formula. Average value and centroids. &nbs p;Calculation strategies. Plotting and measuring. Gauss's normal law in 2D and using it, as done in the Pentagon, to decide how many bombs to dr op on a target.

2.06 More Tools and Measurements

Mathematics.

Separating the variables and integrating to get formulas for the solutions of some differential equations. Integration by parts.  Comp lex numbers and the complex exponential 
       .

Science and math experience.

Formulas for the solutions of the differential equations involved in the chemical model and the spread of infection model. Hyperbolic functions and their relation to trigonometric functions.  Using the complex exponential to help to understand the Mathematica output from the Solve instruction. Gamma function. Integration by parts and integration by iteration. Error propagation in forward iteration. Error reducti on by backwards iteration.

2.07 Traditional Pat Integration Procedures
   

The nasty quotient
       
simplifies to
       
So the nasty quotient is easy to integrate.

Mathematics.

Undetermined coefficients. Complex numbers and partial fractions.  Wild card substitutions with the help of a trigonometric, hyperboli c or ad hoc function.  Integration by parts.

Science and math experience.

Not much, although the experience gained from trying the method of undetermined coefficients is good experience in setting up and solving system s of linear equations.