I absolutely love this joke. The integral looks diabolical but can be computed mentally.
For what it’s worth, while it was able to produce an answer to as many decimal places as needed, even Wolfram Alpha was unable to exactly compute this integral. Feel free to click the link if you’d like the (highly suggestive) answer.
Source: https://www.facebook.com/CTYJohnsHopkins/photos/a.323810509981/10151131549924982/?type=3&theater
Posted by John Quintanilla on February 17, 2020
https://meangreenmath.com/2020/02/17/free-wifi-joke/
I credit Math With Bad Drawings for this new weapon in my arsenal of awful mathematical puns.
Posted by John Quintanilla on February 10, 2020
https://meangreenmath.com/2020/02/10/my-favorite-one-liners-part-115/
Often intuitive appeals for the proof of the Product Rule rely on pictures like the following:
The above picture comes from https://mrchasemath.com/2017/04/02/the-product-rule/, which notes the intuitive appeal of the argument but also its lack of rigor.
My preferred technique is to use the above rectangle picture but make it more rigorous. Assuming that the functions 
In other words,
![f(x+h) g(x+h) - f(x) g(x) = f(x+h) [g(x+h) - g(x)] + [f(x+h) - f(x)] g(x)](https://s0.wp.com/latex.php?latex=f%28x%2Bh%29+g%28x%2Bh%29+-+f%28x%29+g%28x%29+%3D+f%28x%2Bh%29+%5Bg%28x%2Bh%29+-+g%28x%29%5D+%2B+%5Bf%28x%2Bh%29+-+f%28x%29%5D+g%28x%29&bg=f3f3f3&fg=888888&s=0 "f(x+h) g(x+h) - f(x) g(x) = f(x+h) [g(x+h) - g(x)] + [f(x+h) - f(x)] g(x)")
or
This gives a geometrical way of explaining this otherwise counterintuitive step for students not used to adding by a form of 0. I make a point of noting that we took one term, 
For what it’s worth, a Google Images search for proofs of the Product Rule yielded plenty of pictures like the one at the top of this post but did not yield any pictures remotely similar to the green and blue rectangles above. This suggests to me that the above approach of motivating this critical step of this derivation might not be commonly known.
Once students have been introduced to the idea of adding by a form of 0, my experience is that the proof of the Quotient Rule is much more palatable. I’m unaware of a geometric proof that I would be willing to try with students (a description of the best attempt I’ve seen can be found here), and so adding by a form of 0 becomes unavoidable. The proof begins
At this point, I ask my students what we should add and subtract this time to complete the derivation. Given the previous experience with the Product Rule, students are usually quick to chose one factor from the first term and another factor from the second term, usually picking 
P.S.
:
Posted by John Quintanilla on January 24, 2020
https://meangreenmath.com/2020/01/24/adding-by-a-form-of-0-part-2/
Adding by a form of 0, or adding and subtracting the same quantity, is a common technique in mathematical proofs. For example, this technique is used in the second step of the standard proof of the Product Rule in calculus:
Or the proof of the Quotient Rule:
This is a technique that we expect math majors to add to their repertoire of techniques as they progress through the curriculum. I forget the exact proof, but I remember that, when I was a student in honors calculus, we had some theorem that required an argument of the form
But while this is a technique that expect students to master, there’s no doubt that this looks utterly foreign to a student first encountering this technique. After all, in high school algebra, students would simplify something like 
In this brief series, I’d like to give some thoughts on getting students comfortable with this technique.
Posted by John Quintanilla on January 20, 2020
https://meangreenmath.com/2020/01/20/adding-by-a-form-of-0-part-1/
Posted by John Quintanilla on March 25, 2019
https://meangreenmath.com/2019/03/25/c-is-for-constant-of-integration-and-thats-good-enough-for-me/
Posted by John Quintanilla on March 22, 2019
https://meangreenmath.com/2019/03/22/derivative-of-1-x/
“I had learned to do integrals by various methods shown in a book that my high school physics teacher Mr. Bader had given me. [It] showed how to differentiate parameters under the integral sign — it’s a certain operation. It turns out that’s not taught very much in the universities; they don’t emphasize it. But I caught on how to use that method, and I used that one damn tool again and again. [If] guys at MIT or Princeton had trouble doing a certain integral, [then] I come along and try differentiating under the integral sign, and often it worked. So I got a great reputation for doing integrals, only because my box of tools was different from everybody else’s, and they had tried all their tools on it before giving the problem to me.” (Surely you’re Joking, Mr. Feynman!)
I read Surely You’re Joking, Mr. Feynman! dozens of times when I was a teenager, and I was always curious about exactly what this integration technique actually was. So I enjoyed reading this article about the Leibniz Integration Rule: https://medium.com/dialogue-and-discourse/richard-feynmans-integral-trick-e7afae85e25c
Posted by John Quintanilla on March 8, 2019
https://meangreenmath.com/2019/03/08/richard-feynmans-integral-trick/
I enjoyed this reflective piece from Math with Bad Drawings about determining whether 
Short story: 
Posted by John Quintanilla on February 15, 2019
https://meangreenmath.com/2019/02/15/powers-great-and-small/
Posted by John Quintanilla on May 28, 2018
https://meangreenmath.com/2018/05/28/increasingly-difficult-integrals/
I tried a new wise-crack in class recently, and it was a rousing success. My math majors had trouble recalling basic facts about tests for convergent and divergent series, and so I projected onto the front screen the Official Repository of all Knowledge (www.google.com) and searched for “divergent series” to “help” them recall their prior knowledge.
Worked like a charm.
Posted by John Quintanilla on April 27, 2018
https://meangreenmath.com/2018/04/27/my-favorite-one-liners-part-111/
![[(fg)(x)]' = \displaystyle \lim_{h \to 0} \frac{f(x+h) g(x+h) - f(x) g(x)}{h}](https://s0.wp.com/latex.php?latex=%5B%28fg%29%28x%29%5D%27+%3D+%5Cdisplaystyle+%5Clim_%7Bh+%5Cto+0%7D+%5Cfrac%7Bf%28x%2Bh%29+g%28x%2Bh%29+-+f%28x%29+g%28x%29%7D%7Bh%7D&bg=f3f3f3&fg=888888&s=0 "[(fg)(x)]' = \displaystyle \lim_{h \to 0} \frac{f(x+h) g(x+h) - f(x) g(x)}{h}")
![\displaystyle = \lim_{h \to 0} \frac{f(x+h) [g(x+h) - g(x)]}{h} + \lim_{h\ to 0} \frac{[f(x+h) - f(x)] g(x)}{h}](https://s0.wp.com/latex.php?latex=%5Cdisplaystyle+%3D+%5Clim_%7Bh+%5Cto+0%7D+%5Cfrac%7Bf%28x%2Bh%29+%5Bg%28x%2Bh%29+-+g%28x%29%5D%7D%7Bh%7D+%2B+%5Clim_%7Bh%5C+to+0%7D+%5Cfrac%7B%5Bf%28x%2Bh%29+-+f%28x%29%5D+g%28x%29%7D%7Bh%7D&bg=f3f3f3&fg=888888&s=0 "\displaystyle = \lim_{h \to 0} \frac{f(x+h) [g(x+h) - g(x)]}{h} + \lim_{h\ to 0} \frac{[f(x+h) - f(x)] g(x)}{h}")
![\left[\left( \displaystyle \frac{f}{g} \right)(x) \right]' = \displaystyle \lim_{h \to 0} \frac{ \displaystyle \frac{f(x+h)}{ g(x+h)} - \frac{f(x)}{ g(x)}}{h}](https://s0.wp.com/latex.php?latex=%5Cleft%5B%5Cleft%28+%5Cdisplaystyle+%5Cfrac%7Bf%7D%7Bg%7D+%5Cright%29%28x%29+%5Cright%5D%27+%3D+%5Cdisplaystyle+%5Clim_%7Bh+%5Cto+0%7D+%5Cfrac%7B+%5Cdisplaystyle+%5Cfrac%7Bf%28x%2Bh%29%7D%7B+g%28x%2Bh%29%7D+-+%5Cfrac%7Bf%28x%29%7D%7B+g%28x%29%7D%7D%7Bh%7D&bg=f3f3f3&fg=888888&s=0 "\left[\left( \displaystyle \frac{f}{g} \right)(x) \right]' = \displaystyle \lim_{h \to 0} \frac{ \displaystyle \frac{f(x+h)}{ g(x+h)} - \frac{f(x)}{ g(x)}}{h}")
![[(fg)(x)]' = \displaystyle \lim_{h \to 0} \frac{ \displaystyle \frac{f(x+h) g(x) - f(x) g(x+h)}{h }}{g(x) g(x+h)}](https://s0.wp.com/latex.php?latex=%5B%28fg%29%28x%29%5D%27+%3D+%5Cdisplaystyle+%5Clim_%7Bh+%5Cto+0%7D+%5Cfrac%7B+%5Cdisplaystyle+%5Cfrac%7Bf%28x%2Bh%29+g%28x%29+-+f%28x%29+g%28x%2Bh%29%7D%7Bh+%7D%7D%7Bg%28x%29+g%28x%2Bh%29%7D&bg=f3f3f3&fg=888888&s=0 "[(fg)(x)]' = \displaystyle \lim_{h \to 0} \frac{ \displaystyle \frac{f(x+h) g(x) - f(x) g(x+h)}{h }}{g(x) g(x+h)}")
![= \displaystyle \lim_{h \to 0} \frac{ \displaystyle \frac{[f(x+h) - f(x)] g(x)}{h} - \frac{f(x) [g(x+h) - g(x)]}{h }}{g(x) g(x+h)}](https://s0.wp.com/latex.php?latex=%3D+%5Cdisplaystyle+%5Clim_%7Bh+%5Cto+0%7D+%5Cfrac%7B+%5Cdisplaystyle+%5Cfrac%7B%5Bf%28x%2Bh%29+-+f%28x%29%5D+g%28x%29%7D%7Bh%7D+-+%5Cfrac%7Bf%28x%29+%5Bg%28x%2Bh%29+-+g%28x%29%5D%7D%7Bh+%7D%7D%7Bg%28x%29+g%28x%2Bh%29%7D&bg=f3f3f3&fg=888888&s=0 "= \displaystyle \lim_{h \to 0} \frac{ \displaystyle \frac{[f(x+h) - f(x)] g(x)}{h} - \frac{f(x) [g(x+h) - g(x)]}{h }}{g(x) g(x+h)}")
![\displaystyle = \lim_{h \to 0} \left[ \frac{f(x+h) g(x+h) - f(x+h) g(x)}{h} + \frac{f(x+h) g(x) - f(x) g(x)}{h} \right]](https://s0.wp.com/latex.php?latex=%5Cdisplaystyle+%3D+%5Clim_%7Bh+%5Cto+0%7D+%5Cleft%5B+%5Cfrac%7Bf%28x%2Bh%29+g%28x%2Bh%29+-+f%28x%2Bh%29+g%28x%29%7D%7Bh%7D+%2B+%5Cfrac%7Bf%28x%2Bh%29+g%28x%29+-+f%28x%29+g%28x%29%7D%7Bh%7D+%5Cright%5D&bg=f3f3f3&fg=888888&s=0 "\displaystyle = \lim_{h \to 0} \left[ \frac{f(x+h) g(x+h) - f(x+h) g(x)}{h} + \frac{f(x+h) g(x) - f(x) g(x)}{h} \right]")
