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sin(xy)

Algebra is the offer made by the devil to the mathematician. The devil says: I will give you this powerful machine, it will answer any question you like. All you need to do is give me your soul: give up geometry and you will have this marvelous machine.

Sir Michael Atiyah (via curiosamathematica)

#this is such a good quote #and i'm pretty sure the only reason it's resonating with me a lot is thanks to the history and philosophy of mathematics course i took #algebra #geometry

jellobiafrasays

dover mathematics paperbacks (1953, 1956-1959 eds.)

aintnomathbloganymore

I absolutely love Dover publishing. I have so many books from them that are filled with beautiful mathematics.

#books #art

Quora Question: How do I explain recursion to a four-year-old?

Answerer: Explain it to someone a year younger than you and ask them to do the same.

#recursion

images-of-math

A drawing by the 19th century artist J.M.W. Turner, showing how a sphere can cast a shadow on a slanted plane in the shape of an ellipse.

#ellipse #sphere

visualizingmath

Mathematical Spirals

According to Wikipedia, a spiral is a curve which emanates from a central point, getting progressively farther away as it revolves around the point (similar to helices [plural for helix!] which are three-dimensional). Pictured above are some of the most important spirals of mathematics.

Logarithmic Spiral: Equation: r=ae^bθ. I must admit that these are my favorite! Logarithmic spirals are self-similar, basically meaning that the spiral maintains the same shape even as it grows. There are many examples of approximate logarithmic spirals in nature: the spiral arms of galaxies, the shape of nautilus shells, the approach of an insect to a light source, and more. Additionally, the awesome Mandelbrot set features some logarithmic spirals. Fun fact: the Fibonacci spiral is an approximation of the Golden spiral which is only a special case of the Logarithmic spiral.

Fermat’s Spiral: Equation: r= ±θ^(½). This is a type of Archimedean spiral and is also known as the parabolic spiral. Fermat’s spiral plays a role in disk phyllotaxis (the arrangement of leaves in a plant system).

Archimedean Spiral: Equation: r=a+bθ. The Archimedean spiral has the property that the distance between each successive turning of the spiral remains constant. This kind of spiral can have two arms (like in the Fermat’s spiral image), but pictured above is the one-armed version.

Hyperbolic Spiral: Equation: r=a/θ. It is also know as the reciprocal spiral and is the opposite of an Archimedian spiral. It begins at an infinite distance from the pole in the center (for θ starting from zero r = a/θ starts from infinity), and it winds faster and faster around as it approaches the pole; the distance from any point to the pole, following the curve, is infinite.

#spirals

olena

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.

Richard Feynman [2, pp. 71–72]

Differentiating Under the Integral Sign - PDF

(via olena)

#richard feynman #differentiation #integration

everestless-deactivated20190113

#gif #fractals

nogifsallowed

identity

geometrymatters

THINK OF HOW TIME WORKS :)

#gif #wave #circle

intothecontinuum

What do you see? Some kind of band spinning around, or something twisting?

The motion of the first band shown above is ambiguous. Its more obvious that the band on the left is spinning, whereas the band on the right is twisting. The particular dynamics are made evident by watching the two black points on the bands edges. But without these defining features the motion of the gray band is indistinguishable between the two cases.

Perhaps the band is not moving at all, and instead its just the observer’s perspective rotating around this twisted yet inert band!

Can you think of any other shape that might exhibit this kind of symmetry?

Inspired by Bees&Bombs

Mathematica code:

x[ r_, w_, s_, t_] := {r (1 + w*Cos[2 Pi*t]) Cos[2 Pi *s], r (1 + w*Cos[2 Pi*t]) Sin[2 Pi*s] , w*Sin[ 2 Pi*t]} P[ Q_, N_, r_, w_, f_, S_, T_] := Table[x[r, w, -s + n/N, f*t + q/Q + f*n/N] , {s, 1/S, 1, 1/S}, {t, 1/T, 1, 1/T}, {q, 0, Q - 1, 1}, {n, 0, N, 1 }] V = P[2, 200, 1, .25, 1, 50, 50]; Manipulate[ Graphics3D[{ {{Thickness[.001], Line[V[[s, t]]]}, Table[ {FaceForm[GrayLevel[.5]], Opacity[1], EdgeForm[None], Polygon[ {V[[s, t, 1, n]], V[[s, t, 2, n]], V[[s, t, 2, n + 1]], V[[s, t, 1, n + 1]], V[[s, t, 1, n]]}]}, {n, 1, 200, d}]}, {PointSize[p], Black, Point[{V[[s, t, 1, 1]], V[[s, t, 2, 1]]}]}}, Background -> White, Lighting -> "Neutral", PlotRange -> 3.5, ViewPoint -> .4 {1, 1, .6}, Boxed -> False, ImageSize -> 500], {t, 1, 50, 1}, {s, 1, 50, 1}, {d, 1, 5, 1}, {p, {0, .015}}]

charmed-as-a-charmander-deactiv

curiosamathematica

The Google trend for the search query “quadratic formula”.

It repeats in the same pattern every year. Down in summer, up in September, down again in December and up again in spring time before going down again in the summer. And so it goes on forever.

#:)))#quadratic formula

d3lt4-deactivated20180903

"Fibonacci Sequence #3" Art print

Leonardo Fibonacci is an Italian mathematician from the 12th century.

#art #fibanacci #visualization

dominicewan

asweapproachinfinity

Hand drawn hypercube animation.

#tesseract #animation #dimensions

medievalpoc

Math and Science Week!

aseantoo submitted to medievalpoc:

Bhāskarāchārya

[x], [x]

Bhāskarāchārya / Bhāskara II (1114–1185) was an Indian mathematician and astronomer.

Among his many achievements are the following:

1. He was the first person to explain that when you divide by zero, the result is infinity.

2. He was also the first person to note that a positive number has two square roots - a positive and a negative one.

3. He described the principles of differential calculus 500 years before Leibniz and Newton. (He definitively came up with Rolle’s theorem half a millennium before Rolle himself.)

4. He calculated the length of the rotation of the earth around the sun to 365.2588 days - he was just off by 3 minutes.

Intriguingly, his treatise on arithmetic and geometry, Līlāvatī, is named after his daughter. He addresses her as an eager student:

Oh Līlāvatī, intelligent girl, if you understand addition and subtraction, tell me the sum of the amounts 2, 5, 32, 193, 18, 10, and 100, as well as [the remainder of] those when subtracted from 10000.” and “Fawn-eyed child Līlāvatī, tell me, how much is the number [resulting from] 135 multiplied by 12, if you understand multiplication by separate parts and by separate digits. And tell [me], beautiful one, how much is that product divided by the same multiplier?

These invocations have led some to surmise that Līlāvatī, too, was a mathematician.

Image from here: http://mathdept.ucr.edu/pdf/iwm1.pdf

Story of her introduction to math here: http://4go10tales.blogspot.co.uk/2012/06/lilavati.html

Wikipedia on Bhaskaracharya

#history #division by zero #infinity #bhāskarāchārya #līlāvatī

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