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==Explanation==
 
==Explanation==
This comic is a set up to use the joke about {{w|imaginary friend}}s by taking the concept of "{{w|friendly number}}s" into the complex plane, which comprises numbers that have both a real and an imaginary part. Such a pun is both so obvious and so terrible that Cueball's superiors deem that he has lost the right to carry a "math license".  
+
The math paper [[Cueball]] is in the process of describing in this comic, turns out the be noting but an elaborate set up for a joke about {{w|imaginary friend}}s by taking the concept of "{{w|friendly number}}s" into the complex (imaginary) plane, which comprises complex numbers that have both a real and an imaginary part (see details [[#Math|below]]).  
  
This is a recurring theme in earlier xkcd comics, being banned from holding presentations at conferences because said presentations are just elaborate puns. The title text takes the joke a step further, with the added hilarity of making the audience question exactly how Cueball was able to work a {{w|striptease}} into a presentation about genetic engineering and astrophysical rocket study (or possibly genetics and rockets into a striptease...). This is what TV Tropes calls a "[http://tvtropes.org/pmwiki/pmwiki.php/Main/NoodleIncident noodle incident]".
+
Cueball is challenged on this setup by his superiors, specifically the Cueball-like guy sitting at the end of the table, who look straight through his first line up for the joke, and ask him directly if this is just a build-up for this joke. Cueball tries at first to look like he has not idea what he talks about, then lowers his head, in shame, and finally tries to state that ''it might not be'' such a setup. But it is too late now.
 +
 
 +
Such a pun is both so obvious and so terrible that Cueball's superiors, deem that he should no longer have a {{w|Licence to kill (concept)|license to ''math''}} and they thus revoke Cueballs "math license". Of course you do not need a math license, but that is part of the comics concept along the lines mentioned here below and further elaborated in the title text.
 +
 
 +
It is a [[:Category:Banned from conferences|recurring theme]] in earlier xkcd comics that Cueball (or [[Randall]]) ends up being banned from holding presentations at conferences after a presentation turns out to be just an elaborate pun.
 +
 
 +
The title text takes the joke a step further, with the added hilarity of making the audience question exactly how Cueball/Randall was able to work a {{w|striptease}} into a presentation about {{w|genetic engineering}} and {{w|astrophysical}} rocket study (or possibly genetics and rockets into a striptease) and then even manage to lose all three licenses in one go. This is what TV Tropes calls a "[http://tvtropes.org/pmwiki/pmwiki.php/Main/NoodleIncident noodle incident]".
 +
 
 +
The whole comic is basically Randall who makes the joke that Cueball never got around to, but packing it up so we think it is about something else. Randall has often made such feeble jokes, but by putting them into a context where someone listening comment on how bad that joke is or have to explain the joke, it somehow becomes alright, and he can get out with these jokes anyway. (See for instance [[18: Snapple]]).
  
 
===Math===
 
===Math===
An {{w|imaginary number}} is a number that can be written as a real number multiplied by the imaginary unit ''i'', which is defined by its property ''i<sup>2</sup> = -1'' (an impossibility for regular, "real" numbers, for which all squares are positive). The name "imaginary number" was coined in the 17th century as a derogatory term, since such numbers were regarded by some as fictitious or useless, but over time many applications in science and engineering have been found.
+
An {{w|imaginary number}} is a number that can be written as a real number multiplied by the imaginary unit ''i'', which is defined by its property ''i<sup>2</sup> = -1'' (an impossibility for regular, "{{w|real numbers}}", for which all squares are positive). The name "imaginary number" was coined in the 17th century as a derogatory term, since such numbers were regarded by some as fictitious or useless, but over time many applications in science and engineering have been found.
  
An imaginary number ''bi'' can be added to a real number ''a'' to form a {{w|complex number}} of the form ''a+bi'', where ''a'' and ''b'' are called, respectively, the real part and the imaginary part of the complex number. If ''a'' and ''b'' are both integers, the complex number is called a {{w|Gaussian integer}}.
+
An imaginary number ''bi'' can be added to a real number ''a'' to form a {{w|complex number}} of the form ''a+bi'', (the formula shown at the bottom of Cueball's slide ), where ''a'' and ''b'' are called, respectively, the real part and the imaginary part of the complex number. If ''a'' and ''b'' are both integers, the complex number is called a {{w|Gaussian integer}} (as Cueball mentions). The {{w|complex plane}} is an X-Y plot with a on the X axis and b on the Y axis. (Such a plane is shown at the bottom of Cueball's slide).
  
Joel Bradbury has a wonderful explanation of {{w|friendly number}}s on [http://www.joelbradbury.net/notes/friendly_numbers his site]:
+
Joel Bradbury (once) had the below cited and wonderful explanation of {{w|friendly number}}s on his site:
  
:What are Friendly Numbers?  
+
:What are Friendly Numbers?
 
:We need first to define a divisor function over the integers, written σ(n) if you're so inclined. To get it first we get all the integers that divide into n. So for 3, it's 1 and 3. For 4, it's 1, 2, and 4, and for 5 it's only 1 and 5.
 
:We need first to define a divisor function over the integers, written σ(n) if you're so inclined. To get it first we get all the integers that divide into n. So for 3, it's 1 and 3. For 4, it's 1, 2, and 4, and for 5 it's only 1 and 5.
  
 
:Now sum them to get σ(n). So σ(3) = 1 + 3 = 4, or σ(4) = 1 + 2 + 4 = 7, and so on.
 
:Now sum them to get σ(n). So σ(3) = 1 + 3 = 4, or σ(4) = 1 + 2 + 4 = 7, and so on.
  
:For each of these n, there is something called a characteristic ratio. Now that's just the divisors function over the integer itself: σ(n)/n . So the characteristic ratio where n = 6 is σ(6)/6 = 12/6 = 2.
+
:For each of these n, there is something called a characteristic ratio. Now that's just the divisors function over the integer itself: σ(n)/n. (This is the formula shown at the top of Cueball's slide). So the characteristic ratio where n = 6 is σ(6)/6 = 12/6 = 2.
  
:Once you have the characteristic ratio for any integer n, any other integers that share the same characteristic are called friendly with each other. So to put it simply a friendly number is any integer that shares its characteristic ratio with at least one other integer. The converse of that is called a solitary number, where it doesn't share its characteristic with anyone else.
+
:Once you have the characteristic ratio for any integer n, any other integers that share the same characteristic are called friendly with each other. (This is what is written in the frame in Cueball's slide, spelling friendly numbers as ''friendly #s''). So to put it simply a friendly number is any integer that shares its characteristic ratio with at least one other integer. The converse of that is called a solitary number, where it doesn't share its characteristic with anyone else.
  
 
:1, 2, 3, 4 and 5 are solitary. 6 is friendly with 28; σ(6)/6 = (1+2+3+6)/6 = 12/6 = 2 = 56/28 = (1+2+4+7+14+28)/28 = σ(28)/28.
 
:1, 2, 3, 4 and 5 are solitary. 6 is friendly with 28; σ(6)/6 = (1+2+3+6)/6 = 12/6 = 2 = 56/28 = (1+2+4+7+14+28)/28 = σ(28)/28.
  
 
==Transcript==
 
==Transcript==
:[Cueball points to equations on the board.]
+
:[Cueball holding a pointing stick is using it to point at an equation on a panel. He is looking right. There several parts of the panel that can be read. At the top there is a formula. Below is a frame with text. Below again to the left is a X-Y plot with small dots all over all four quadrants, probably indicating the complex numbers with b on the Y and a on the X axis. Finally right of this is yet another formula.]
 
:Cueball: In my paper, I use an extension of the divisor function over the Gaussian integers to generalize the so-called "friendly numbers" into the complex plane.
 
:Cueball: In my paper, I use an extension of the divisor function over the Gaussian integers to generalize the so-called "friendly numbers" into the complex plane.
 +
:Panel:
 +
::σ(n)/n = d(n)
 +
::Friendly #s share d(n)
 +
::For a + bi...
 +
 +
:[The audience to the right of Cueball consist of two Cueball-like guys (one in front and one in the back) and between them are Hairbun, with glasses, and Megan. They sit around a table, only Hairbun is on the near side. The Cueball-like guy sitting to the right is at the end of the table, the other two are on the far side. The Cueball at the end of the table is talking, the other three have turned to look at him:]
 +
:Guy at the end of the table: Hold on. Is this paper simply a giant build-up to an "imaginary friends" pun?
  
:Professor: Hold on. Is this paper simply a giant build-up to an "imaginary friends" pun?
+
:[Back to Cueball who stands speechless.]
  
:[Cueball stands speechless for two panels.]
+
:[One more beat panel with Cueball who now looks down.]
  
:Cueball: It <u>MIGHT</u> not be.
+
:[Zoom out to Cueball and the front end of the table with the Cueball-like guy who has not spoken yet and Hairbun who now looks at Cueball. Cueball looks up again and speaks. The guy at the end of the table speaks off panel.]
:Professor: I'm sorry, we're revoking your math license.
+
:Cueball: It <u>might</u> not be.
 +
:Guy at the end of the table (off panel): I'm sorry, we're revoking your math license.
  
 
{{comic discussion}}
 
{{comic discussion}}
[[Category:Math]]
+
 
 
[[Category:Comics featuring Cueball]]
 
[[Category:Comics featuring Cueball]]
 +
[[Category:Comics featuring Hairbun]]
 +
[[Category:Comics featuring Megan]]
 +
[[Category:Multiple Cueballs]]
 
[[Category:Banned from conferences]]
 
[[Category:Banned from conferences]]
[[Category:Public speaking]]
+
[[Category:Math]]
 
[[Category:Puns]]
 
[[Category:Puns]]

Revision as of 01:44, 11 April 2016

Math Paper
That's nothing. I once lost my genetics, rocketry, and stripping licenses in a single incident.
Title text: That's nothing. I once lost my genetics, rocketry, and stripping licenses in a single incident.

Explanation

The math paper Cueball is in the process of describing in this comic, turns out the be noting but an elaborate set up for a joke about imaginary friends by taking the concept of "friendly numbers" into the complex (imaginary) plane, which comprises complex numbers that have both a real and an imaginary part (see details below).

Cueball is challenged on this setup by his superiors, specifically the Cueball-like guy sitting at the end of the table, who look straight through his first line up for the joke, and ask him directly if this is just a build-up for this joke. Cueball tries at first to look like he has not idea what he talks about, then lowers his head, in shame, and finally tries to state that it might not be such a setup. But it is too late now.

Such a pun is both so obvious and so terrible that Cueball's superiors, deem that he should no longer have a license to math and they thus revoke Cueballs "math license". Of course you do not need a math license, but that is part of the comics concept along the lines mentioned here below and further elaborated in the title text.

It is a recurring theme in earlier xkcd comics that Cueball (or Randall) ends up being banned from holding presentations at conferences after a presentation turns out to be just an elaborate pun.

The title text takes the joke a step further, with the added hilarity of making the audience question exactly how Cueball/Randall was able to work a striptease into a presentation about genetic engineering and astrophysical rocket study (or possibly genetics and rockets into a striptease) and then even manage to lose all three licenses in one go. This is what TV Tropes calls a "noodle incident".

The whole comic is basically Randall who makes the joke that Cueball never got around to, but packing it up so we think it is about something else. Randall has often made such feeble jokes, but by putting them into a context where someone listening comment on how bad that joke is or have to explain the joke, it somehow becomes alright, and he can get out with these jokes anyway. (See for instance 18: Snapple).

Math

An imaginary number is a number that can be written as a real number multiplied by the imaginary unit i, which is defined by its property i2 = -1 (an impossibility for regular, "real numbers", for which all squares are positive). The name "imaginary number" was coined in the 17th century as a derogatory term, since such numbers were regarded by some as fictitious or useless, but over time many applications in science and engineering have been found.

An imaginary number bi can be added to a real number a to form a complex number of the form a+bi, (the formula shown at the bottom of Cueball's slide ), where a and b are called, respectively, the real part and the imaginary part of the complex number. If a and b are both integers, the complex number is called a Gaussian integer (as Cueball mentions). The complex plane is an X-Y plot with a on the X axis and b on the Y axis. (Such a plane is shown at the bottom of Cueball's slide).

Joel Bradbury (once) had the below cited and wonderful explanation of friendly numbers on his site:

What are Friendly Numbers?
We need first to define a divisor function over the integers, written σ(n) if you're so inclined. To get it first we get all the integers that divide into n. So for 3, it's 1 and 3. For 4, it's 1, 2, and 4, and for 5 it's only 1 and 5.
Now sum them to get σ(n). So σ(3) = 1 + 3 = 4, or σ(4) = 1 + 2 + 4 = 7, and so on.
For each of these n, there is something called a characteristic ratio. Now that's just the divisors function over the integer itself: σ(n)/n. (This is the formula shown at the top of Cueball's slide). So the characteristic ratio where n = 6 is σ(6)/6 = 12/6 = 2.
Once you have the characteristic ratio for any integer n, any other integers that share the same characteristic are called friendly with each other. (This is what is written in the frame in Cueball's slide, spelling friendly numbers as friendly #s). So to put it simply a friendly number is any integer that shares its characteristic ratio with at least one other integer. The converse of that is called a solitary number, where it doesn't share its characteristic with anyone else.
1, 2, 3, 4 and 5 are solitary. 6 is friendly with 28; σ(6)/6 = (1+2+3+6)/6 = 12/6 = 2 = 56/28 = (1+2+4+7+14+28)/28 = σ(28)/28.

Transcript

[Cueball holding a pointing stick is using it to point at an equation on a panel. He is looking right. There several parts of the panel that can be read. At the top there is a formula. Below is a frame with text. Below again to the left is a X-Y plot with small dots all over all four quadrants, probably indicating the complex numbers with b on the Y and a on the X axis. Finally right of this is yet another formula.]
Cueball: In my paper, I use an extension of the divisor function over the Gaussian integers to generalize the so-called "friendly numbers" into the complex plane.
Panel:
σ(n)/n = d(n)
Friendly #s share d(n)
For a + bi...
[The audience to the right of Cueball consist of two Cueball-like guys (one in front and one in the back) and between them are Hairbun, with glasses, and Megan. They sit around a table, only Hairbun is on the near side. The Cueball-like guy sitting to the right is at the end of the table, the other two are on the far side. The Cueball at the end of the table is talking, the other three have turned to look at him:]
Guy at the end of the table: Hold on. Is this paper simply a giant build-up to an "imaginary friends" pun?
[Back to Cueball who stands speechless.]
[One more beat panel with Cueball who now looks down.]
[Zoom out to Cueball and the front end of the table with the Cueball-like guy who has not spoken yet and Hairbun who now looks at Cueball. Cueball looks up again and speaks. The guy at the end of the table speaks off panel.]
Cueball: It might not be.
Guy at the end of the table (off panel): I'm sorry, we're revoking your math license.


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Discussion

Shouldn't it say something about the whole math licence, and that you don't actually need a licence to do math? 108.162.231.228 21:01, 31 October 2013 (UTC)Synthetica

Despite what this comic implies, the divisor function is defined over the Gaussian integers. There still is a problem, though. If a divides b, then so does -a, along with ai and -ai. The divisors will inevitably sum to zero. You could get around this by ignoring all the numbers that aren't in a given quadrant. I personally like the idea of using ones where the real part is greater than the imaginary part (although that still does become a problem with multiples of 1+i). This way, a friend of a natural number will also be a natural number (though it's only the same as what you'd get normally if all the factors are three mod four). 199.27.128.167 (talk) (please sign your comments with ~~~~)

I do not agree. Here is how it should work. You should define that a divides b if and only if there is a natural number n such that an = b. This way, natural numbers don't get new divisors when you move to the Gaussian plane. Consequently the extended sigma function gives the same value as the classical one when applied to a natural number. So, natural numbers will be friends according to the new definition if and only if they are friends according to the old definition and we are indeed allowed to say that the new definition extends the old one (Burghard von Karger). 162.158.93.28 (talk) (please sign your comments with ~~~~)
So you're saying that the only friends imaginary friends have are imaginary? guess who (if you want to | what i have done) 23:21, 2 November 2023 (UTC)

Does someone care to hazard a guess about the alt text? Are there any possible papers that could have been written about those three fields? 173.245.53.186 15:04, 5 January 2014 (UTC)

I think no one's noticed the "Straight man's deadpan stare" in panels 3 and 4. After being rudely interrupted in panel two, the lecturer stares silently at the person who stopped him in panel 3. Note the shape of the lecturer's head: his forehead and chin are facing towards the right as revealed by the angled features at the top and bottom of his head. In panel 4 the lecturer turns and stares at the reader and stands silent. Note the completely round shape of the head. This is the classic deadpan stare. Also, am I the only one who assumed that Cueball himself is the lecturer and the person interrupting him is likely the proffessor of the class?ExternalMonolog (talk) 20:14, 21 January 2014 (UTC)ExternalMonolog

I don't know. In panel three DOES look straight at the commenter in the audience in a deadpan way, like he'd been caught unawares by the person's observation, but in panel four seems to look down, head tilted towards the floor as if wondering "aww shit, now what do I do?" Or like he felt slightly ashamed of being caught. 108.162.216.76 22:56, 27 February 2014 (UTC)
I thought it was pretty plainly evident that Cueball is the presenter - going along with the XKCD theme of banning/revoking Cueball's privilege due to "inappropriately" wasting people's time at an ostensibly serious event. Also, in relative agreement with 108.162.216.76, I think that Panel 3 is his feeble attempt to continue to look serious (or straight/deadpan) while thinking of a way to respond, followed in Panel 4 with a slightly defeated shoulder/head slump (giving up with trying to perpetuate his premise). Panel 5 could be viewed as a plain admission, but I prefer to see it as a final, hail-Mary attempt to maintain the graces of the audience without actually lying to them. -- Brettpeirce (talk) 16:09, 5 March 2014 (UTC)
They are probably beat panels more than anything else. -Pennpenn 108.162.250.155 00:13, 27 March 2015 (UTC)

There's a joke among amateur songwriters that a forced rhyme or other dubious technique might lead to revoking the writer's "poetic license." Gmcgath (talk) 22:08, 30 October 2016 (UTC)