Editing 2566: Decorative Constants
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==Explanation== | ==Explanation== | ||
+ | {{incomplete|Created by a DECORATIVE BOT - What is the formula representing when removing the two decorative constants? What had Euler and Bernouli done since a decorative constant is a tribute to them? They where math wiz but did they put in such needless constants in their work? Also seems like the 1/2 is not really such an example, just Randall that jokes. - Do NOT delete this tag too soon.}} | ||
This is another one of [[Randall|Randall's]] [[:Category:Tips|Tips]], this time a Math Tip. | This is another one of [[Randall|Randall's]] [[:Category:Tips|Tips]], this time a Math Tip. | ||
− | + | He gives an example of a complex looking equation labeled 4-15, but since 𝔻 and μ are "decorative", the equation can be reduced to T = m<sub>0</sub>(r<sub>out</sub> - r<sub>in</sub>). The decorative symbols can be interpreted as constants 𝔻 = μ = 1, in which case the implied operations of multiplication and exponentiation make sense. The 𝔻 is is double-struck ("blackboard bold"). Mathematicians, who are always searching for more symbols, have taken to distinguishing things represented by the same letter by using different fonts, such as d, ''d'', '''d''', '''''d''''', D, ''D'', '''D''', '''''D''''', 𝒹, 𝒟, 𝖉, 𝕯, ∂, 𝕕, and 𝔻. The double-struck font is easier to write on a blackboard than a proper bold letter and often represents a set, such as ℝ for the set of real numbers or ℂ for the set of complex numbers. 𝔻 can represent the unit disk in the complex plane, the set of decimal fractions, or the set of split-complex numbers. μ is the Greek lowercase mu and has many uses in mathematics and science. Here it has a bar, which could indicate a number of things, including the complex conjugate. Intriguingly, μ is the symbol in statistics for the population mean, and the overbar represents the sample mean, so this could represent a random variable which is the average of a sample of means μ<sub>i</sub> of different populations in some larger ensemble of populations. | |
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− | The decorative symbols can be interpreted as constants 𝔻 = μ | ||
− | + | This all leads up to the math tip: If one of your equations ever looks too simple, try adding some purely decorative constants. | |
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Other examples of well known equations that are profound but look simple include | Other examples of well known equations that are profound but look simple include | ||
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:''F'' = ''ma'' ({{w|Newton's Second Law}}), | :''F'' = ''ma'' ({{w|Newton's Second Law}}), | ||
:''V'' = ''IR'' ({{w|Ohm's Law}}), and | :''V'' = ''IR'' ({{w|Ohm's Law}}), and | ||
− | :''G<sub>μν</sub>'' + Λ ''g<sub>μν</sub>'' = ''κT<sub>μν</sub>'' ({{w|Einstein field equations}}) | + | :''G<sub>μν</sub>'' + Λ ''g<sub>μν</sub>'' = ''κT<sub>μν</sub>'' ({{w|Einstein field equations}}). |
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− | + | Of these, only the Einstein equations have been spiced up with decorative indices (which actually hide a system of ten nonlinear partial differential equations). | |
− | + | In the title text Randall mentions the {{w|Drag equation}}. In fluid dynamics, the drag equation is a formula used to calculate the force of drag experienced by an object due to movement through a fully enclosing fluid. The equation is ''F''<sub>d</sub> = ½''ρu''<sup>2</sup>''c''<sub>d</sub>''A''. | |
− | The | + | Randall jokes that the factor of ½ in the equation is meaningless and purely decorative, since the drag coefficients, ''c''<sub>d</sub>, are already unitless and could just as easily be half as big thus leaving out the ½ in front of the equation. The ½ is thus just an example of a "decorative constant." The usual reason for including the factor of ½ is that it is part of the formula for kinetic energy that appears in the derivation of the drag equation. However, modern treatments are so condensed that this factor of ½ is often smuggled in with no explanation. Since we can choose the constants to be whatever we want, there is ultimately no reason not to absorb the ½ into the drag coefficient ''c''<sub>d</sub>, but that does not mean it is totally unmotivated. Still, Randall claims there is a textbook that just calls it "a traditional tribute to Euler and Bernoulli," probably referring to renowned mathematician {{w|Leonhard Euler}} and {{w|Daniel Bernoulli}}, a mathematician and member of the renowned Bernoulli family of mathematicians. Daniel Bernoulli is known for modifying the definition of ''vis viva'' (what we now call kinetic energy) from ''mv''<sup>2</sup> to ½''mv''<sup>2</sup>, as motivated by the derivation from the impulse equation. In 1741, he wrote |
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− | Daniel Bernoulli is known for modifying the definition of ''vis viva'' (what we now call kinetic energy) from ''mv''<sup>2</sup> to ½''mv''<sup>2</sup>, as motivated by the derivation from the impulse equation. In 1741, he wrote | ||
:[Define ''vis viva''] esse ½ ''mvv'' = ∫''pdx''. | :[Define ''vis viva''] esse ½ ''mvv'' = ∫''pdx''. | ||
That is, "define ''vis viva'' to be ½ ''mv''<sup>2</sup> = ∫''p''d''x''," where ''p'' is the force (from ''pressione'') and d''x'' is the differential of position (infinitesimal displacement). Today, this equation says that the kinetic energy imparted to an object at rest equals the work done on it. | That is, "define ''vis viva'' to be ½ ''mv''<sup>2</sup> = ∫''p''d''x''," where ''p'' is the force (from ''pressione'') and d''x'' is the differential of position (infinitesimal displacement). Today, this equation says that the kinetic energy imparted to an object at rest equals the work done on it. | ||
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==Transcript== | ==Transcript== | ||
:[A small panel only with text. Written as an excerpt from a mathematical text book. Begins with a number for an equation, then follows the equation written in larger letters and symbols. And below are explanations of each term in the equation. The μ has a bar over the top and the D has a double vertical line.] | :[A small panel only with text. Written as an excerpt from a mathematical text book. Begins with a number for an equation, then follows the equation written in larger letters and symbols. And below are explanations of each term in the equation. The μ has a bar over the top and the D has a double vertical line.] | ||
:Eq. 4-15 | :Eq. 4-15 | ||
− | :<big>T = | + | :<big>T = Dm<sub>0</sub>(r<sub>out</sub> - r<sub>in</sub>)<sup>μ</sup></big> |
:T: Net rate | :T: Net rate | ||
:m<sub>0</sub>: Unit mass | :m<sub>0</sub>: Unit mass | ||
:(r<sub>out</sub>-r<sub>in</sub>): Flow balance<br> | :(r<sub>out</sub>-r<sub>in</sub>): Flow balance<br> | ||
− | : | + | :D, μ: Decorative |
:[Caption below the panel:] | :[Caption below the panel:] | ||
:Math tip: If one of your equations ever looks too simple, try adding some purely decorative constants. | :Math tip: If one of your equations ever looks too simple, try adding some purely decorative constants. | ||
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{{comic discussion}} | {{comic discussion}} |