The truly short answer is that π is not just related to circles. It’s a magic number that shows up everywhere in the laws of mathematics, along with e. You just happen to know it best from circles, unless you study more advanced math.

The truly short answer is that π is not just related to circles. It’s a magic number that shows up everywhere in the laws of mathematics, along with e. You just happen to know it best from circles, unless you study more advanced math.

Okay, other people have already given you nice, simple answers about how circles are fundamental objects, so I hope you’ll permit me to stretch the ELI5 requirement until it writhes in pain.

The true, deep, fundamental reason that pi shows up everywhere is that the *exponential function* shows up everywhere.

The exponential function is a function that is equal to it’s own derivative. If you fix exp(0) = 1, it’s *the only* function equal to it’s own derivative.

This is *huge*. I can’t emphasize enough how fundamental of a fact this is. The exponential function is a *fixed point*, an eigenvector of sorts, of the all-important differentiation operator. That means whenever you’re dealing with *anything* differentiable, any relationship between derivatives of functions, this function exp magically appears. It is often called “the most important function in mathematics”.

The most amazing thing? This exponential function is perfectly well defined on the entire complex plane. Look on the real axis, you get exponential growth/decay. Look on the imaginary axis, you get *cyclic motion*. This function *repeats*, on the imaginary axis, with a period of 2(pi)(i). This period is a fundamental constant of a deeply fundamental function, so therefore pi is a fundamental constant in math.

(The familiar sin and cos functions pop right out from the complex exponential. This is where the famous e^pi ^i +1 = 0 comes from.)

I would say *that’s* the real reason why pi is so universal. That’s why it shows up *everywhere*. It’s because such a vast amount of math boils down to manipulations of the complex exponential function. Sure, pi is also about circles, but that’s because the exponential function is the basic building block of the more fundamental idea of *cyclic motion*, for which circles are a convenient visualization.

Okay, other people have already given you nice, simple answers about how circles are fundamental objects, so I hope you’ll permit me to stretch the ELI5 requirement until it writhes in pain.

The true, deep, fundamental reason that pi shows up everywhere is that the *exponential function* shows up everywhere.

The exponential function is a function that is equal to it’s own derivative. If you fix exp(0) = 1, it’s *the only* function equal to it’s own derivative.

This is *huge*. I can’t emphasize enough how fundamental of a fact this is. The exponential function is a *fixed point*, an eigenvector of sorts, of the all-important differentiation operator. That means whenever you’re dealing with *anything* differentiable, any relationship between derivatives of functions, this function exp magically appears. It is often called “the most important function in mathematics”.

The most amazing thing? This exponential function is perfectly well defined on the entire complex plane. Look on the real axis, you get exponential growth/decay. Look on the imaginary axis, you get *cyclic motion*. This function *repeats*, on the imaginary axis, with a period of 2(pi)(i). This period is a fundamental constant of a deeply fundamental function, so therefore pi is a fundamental constant in math.

(The familiar sin and cos functions pop right out from the complex exponential. This is where the famous e^pi ^i +1 = 0 comes from.)

I would say *that’s* the real reason why pi is so universal. That’s why it shows up *everywhere*. It’s because such a vast amount of math boils down to manipulations of the complex exponential function. Sure, pi is also about circles, but that’s because the exponential function is the basic building block of the more fundamental idea of *cyclic motion*, for which circles are a convenient visualization.

Any angle that exists can be interpreted as part of a circle so you always have a reference to PI

Any angle that exists can be interpreted as part of a circle so you always have a reference to PI

It’s not “only related to a circle”. It figures heavily in Trigonometry, and triangles/angles are absolutely everywhere in science/nature.

It’s not “only related to a circle”. It figures heavily in Trigonometry, and triangles/angles are absolutely everywhere in science/nature.

One big reason is that the universe is essentially radially symmetric. In the grand scheme of things, forces will act in all directions without preference. This behavior favors spheres as the ideal shape in the universe to balance against forces.

One big reason is that the universe is essentially radially symmetric. In the grand scheme of things, forces will act in all directions without preference. This behavior favors spheres as the ideal shape in the universe to balance against forces.