Editing 2117: Differentiation and Integration
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==Explanation== | ==Explanation== | ||
− | This comic | + | {{incomplete|Created by a BESSEL FUNCTION? Please mention here why this explanation isn't complete. Do NOT delete this tag too soon.}} |
+ | This comic provides a {{w|flowchart}} purporting to show the process of differentiation, and another for integration. | ||
{{w|Derivative|Differentiation}} and {{w|Antiderivative|Integration}} are two major components of {{w|calculus}}. As many Calculus 2 students are painfully aware, integration is much more complicated than the differentiation it undoes. | {{w|Derivative|Differentiation}} and {{w|Antiderivative|Integration}} are two major components of {{w|calculus}}. As many Calculus 2 students are painfully aware, integration is much more complicated than the differentiation it undoes. | ||
− | However, Randall dramatically overstates this point here. After the first step of integration, Randall assumes that any integration can not be solved so simply, and then dives into a step named "????", suggesting that it is unknowable how to proceed. The rest of the flowchart is (we can assume deliberately) even harder to follow, and does not reach a conclusion. This is in contrast to the simple, straightforward flowchart for differentiation. The fact that the arrows in the bottom of the integration part leads to nowhere indicates that "Phone calls to mathematicians", "Oh no" and "Burn the evidence" are not final steps in the difficult journey. The flowchart could be extended by Randall to God- | + | However, Randall dramatically overstates this point here. After the first step of integration, Randall assumes that any integration can not be solved so simply, and then dives into a step named "????", suggesting that it is unknowable how to proceed. The rest of the flowchart is (we can assume deliberately) even harder to follow, and does not reach a conclusion. This is in contrast to the simple, straightforward flowchart for differentiation. The fact that the arrows in the bottom of the integration part leads to nowhere indicates that "Phone calls to mathematicians", "Oh no" and "Burn the evidence" are not final steps in the difficult journey. The flowchart could be extended by Randall to God-know-where extents. |
− | It should be noted that Randall slightly undermines his point by providing four different methods, and an "etc", | + | It should be noted that Randall slightly undermines his point by providing four different methods, and an "etc", for attempting differentiation with no guidelines for selecting between them. |
===Differentiation=== | ===Differentiation=== | ||
'''{{w|Chain rule}}''' | '''{{w|Chain rule}}''' | ||
− | For any <math> \frac{d}{dx}f(x)=f'(x)</math> and <math> \frac{d}{dx}g(x)=g'(x) </math>, it follows that <math> \frac{d}{dx}(f(g(x)))=f'(g(x)) | + | For any <math> \frac{d}{dx}f(x)=f'(x)</math> and <math> \frac{d}{dx}g(x)=g'(x) </math>, it follows that <math> \frac{d}{dx}(f(g(x)))=f'(g(x))*g'(x)</math>. |
'''{{w|Power Rule}}''' | '''{{w|Power Rule}}''' | ||
− | For any <math> f(x)= | + | For any <math> f(x)=x^a </math>, it follows that <math> \frac{d}{dx}f(x)=a*x^{a-1} </math>. |
'''{{w|Quotient rule}}''' | '''{{w|Quotient rule}}''' | ||
− | For any <math> \frac{d}{dx}f(x)=f'(x)</math> and <math> \frac{d}{dx}g(x)=g'(x) </math>, it follows that <math> \frac{d}{dx} \frac{f(x)}{g(x)}=\frac{f'(x) | + | For any <math> \frac{d}{dx}f(x)=f'(x)</math> and <math> \frac{d}{dx}g(x)=g'(x) </math>, it follows that <math> \frac{d}{dx} \frac{f(x)}{g(x)}=\frac{f'(x)g(x)-f(x)g'(x)}{(g(x))^2}</math> if <math>g(x)\ne 0</math>. |
'''{{w|Product rule}}''' | '''{{w|Product rule}}''' | ||
− | For any <math> \frac{d}{dx}f(x)=f'(x)</math> and <math> \frac{d}{dx}g(x)=g'(x) </math>, it follows that <math> \frac{d}{dx}(f(x) | + | For any <math> \frac{d}{dx}f(x)=f'(x)</math> and <math> \frac{d}{dx}g(x)=g'(x) </math>, it follows that <math> \frac{d}{dx}(f(x)*g(x))=f'(x)*g(x)+f(x)*g'(x)</math>. |
===Integration=== | ===Integration=== | ||
'''{{w|Integration by parts}}''' | '''{{w|Integration by parts}}''' | ||
− | The "product rule" run backwards. Since <math>(uv)' = uv' + u'v</math>, it follows that by integrating both sides you get <math> uv = \int u dv + \int v du</math>, which is more commonly written as <math>\int u dv = uv - \int v du</math>. By finding appropriate values for functions <math>u, v</math> such that your problem is in the form <math>\int u dv</math>, your problem ''may'' be simplified | + | The "product rule" run backwards. Since <math>(uv)' = uv' + u'v</math>, it follows that by integrating both sides you get <math> uv = \int u dv + \int v du</math>, which is more commonly written as <math>\int u dv = uv - \int v du</math>. By finding appropriate values for functions <math>u, v</math> such that your problem is in the form <math>\int u dv</math>, your problem ''may'' be simplified. |
'''{{w|Integration by substitution|Substitution}}''' | '''{{w|Integration by substitution|Substitution}}''' | ||
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'''{{w|Cauchy's integral formula|Cauchy's Formula}}''' | '''{{w|Cauchy's integral formula|Cauchy's Formula}}''' | ||
− | Cauchy's Integral formula is a result in complex analysis that relates the value of a contour integral in the complex plane to properties of the singularities in the interior of the contour. | + | Cauchy's Integral formula is a result in complex analysis that relates the value of a contour integral in the complex plane to properties of the singularities in the interior of the contour. It is often used to compute integrals on the real line by extending the path of the integral from the real line into the complex plane to apply the formula, then proving that the integral from the parts of the contour not on the real line has value zero. |
'''{{w|Partial_fraction_decomposition#Application_to_symbolic_integration|Partial Fractions}}''' | '''{{w|Partial_fraction_decomposition#Application_to_symbolic_integration|Partial Fractions}}''' | ||
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Partial fractions is a technique for breaking up a function that comprises one polynomial divided by another into a sum of functions comprising constants over the factors of the original denominator, which can easily be integrated into logarithms. | Partial fractions is a technique for breaking up a function that comprises one polynomial divided by another into a sum of functions comprising constants over the factors of the original denominator, which can easily be integrated into logarithms. | ||
− | ''' | + | '''{{w|Install Mathematica}}''' |
− | Mathematica is a modern technical computing system spanning most areas. One of its features is to compute mathematical functions. This step in the flowchart is | + | {{w|Mathematica}} is a modern technical computing system spanning most areas. One of its features is to compute mathematical functions. This step in the flowchart is install and use Mathematica to compute to do the integration for you. |
'''{{w|Riemann integral|Riemann Integration}}''' | '''{{w|Riemann integral|Riemann Integration}}''' | ||
− | + | The Riemann integral is a definition of definite integration. Elementary textbooks on calculus sometimes present finding a definite integral as a process of approximating an area by strips of equal width and then taking the limit as the strips become narrower. Riemann integration removes the requirement that the strips have equal width, and so is a more flexible definition. However there are still many functions for which the Riemann integral doesn't converge, and consideration of these functions leads to the Lesbegue Integral. Riemann integration is not a method of calculus appropriate for finding the anti-derivative of an elementary function. | |
− | The Riemann integral is a definition of definite integration. | ||
'''{{w|Stokes' Theorem}}''' | '''{{w|Stokes' Theorem}}''' | ||
+ | ??? | ||
− | + | '''{{w|Risch algorithm}}''' | |
− | + | The Risch algorithm is a notoriously complex procedure that, given a certain class of symbolic integrand, either finds a symbolic integral or proves that no elementary integral exists. (Technically it is only a semi-algorithm, and cannot produce an answer unless it can determine if a certain symbolic expression is {{w|Constant problem|equal to 0}} or not.) Many computer algebra systems have chosen to implement only the simpler Risch-Norman algorithm, which does not come with the same guarantee. A series of extensions to the Risch algorithm extend the class of allowable functions to include (at least) the error function and the logarithmic integral. | |
− | '''{{w|Risch | ||
− | |||
− | The Risch algorithm is a notoriously complex procedure that, given a certain class of symbolic integrand, either finds a symbolic integral or proves that no elementary integral exists. (Technically it is only a semi-algorithm, and cannot produce an answer unless it can determine if a certain symbolic expression is {{w|Constant problem|equal to 0}} or not.) Many computer algebra systems have chosen to implement only the simpler Risch-Norman algorithm, which does not come with the same guarantee. A series of extensions to the Risch algorithm extend the class of allowable functions to include (at least) the error function and the logarithmic integral | ||
'''{{w|Bessel function}}''' | '''{{w|Bessel function}}''' | ||
− | + | The Bessel function is a second-order differential equation used in solving problems in cylindrical and spherical coordinate systems. | |
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'''{{w|Symbolic integration}}''' | '''{{w|Symbolic integration}}''' | ||
+ | Mentioned in the title text. ??? | ||
− | + | ''' Burn the evidence ''' | |
+ | In a parody of detective novels, this may refer to the burning of your work to avoid the shame of being unable to solve the integration problem. | ||
+ | Alternatively, this could be an ironic hint to the fact that in order to find the integral, it may even be necessary to break the law or upset higher powers, so that the negative consequences of a persecution can only be avoided by destroying the evidence. | ||
==Transcript== | ==Transcript== | ||
+ | {{incomplete transcript|Do NOT delete this tag too soon.}} | ||
:[Two flow charts are shown.] | :[Two flow charts are shown.] | ||
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::Etc. | ::Etc. | ||
:Done? | :Done? | ||
− | |||
::Yes | ::Yes | ||
+ | ::No | ||
:Done! | :Done! | ||
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::Oh No | ::Oh No | ||
::Burn the Evidence | ::Burn the Evidence | ||
− | :: | + | <!--::More arrows pointing out of the image to suggest more steps--> |
{{comic discussion}} | {{comic discussion}} | ||
[[Category:Analysis]] | [[Category:Analysis]] | ||
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