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Squigonometry

From EverybodyWiki Bios & Wiki



Squigonometry or p-trigonometry is a branch of mathematics that extends traditional trigonometry to shapes other than circles, particularly to squircles, in the p-norm. Unlike trigonometry, which deals with the relationships between angles and side lengths of triangles and uses trigonometric functions, squigonometry focuses on analogous relationships within the context of a unit squircle.

Squigonometric functions are mostly used to solve certain indefinite integrals, using a method akin to trigonometric substitution.[1] This approach allows for the integration of functions that are otherwise computationally difficult to handle.

Squigonometry has been applied to find expressions for the volume of superellipsoids, such as the superegg.[2]

Etymology

The term squigonometry is a portmanteau of squircle and trigonometry. The first use of the term "squigonometry" is undocumented; the coining of the word possibly emerged from mathematical curiosity and the need to solve problems involving squircle geometries. As mathematicians sought to generalize trigonometric ideas beyond circular shapes, they naturally extended these concepts to squircles, leading to the creation of new functions.

Nonetheless, it is well established that the idea of parametrizing other curves that lack the circle’s perfection has been around for around 300 years.[3] Over the span of three centuries, many mathematicians have thought about using functions similar to trigonometric functions to parameterize these generalized curves.

Squigonometric functions

Cosquine and squine

Definition through unit squircle

Unit squircle for different values of p

The cosquine and squine functions, denoted as cqp(t) and sqp(t), can be defined analogously to trigonometric functions on a unit circle, but instead using the coordinates of points on a unit squircle, described by the equation:

|x|p+|y|p=1

where p is a real number greater than or equal to 1. Here x corresponds to cqp(t) and y corresponds to sqp(t)

Notably, when p=2, the squigonometric functions coincide with the trigonometric functions.

Definition through differential equations

Similarly to how trigonometric functions are defined through differential equations, the cosquine and squine functions are also uniquely determined[4] by solving the coupled initial value problem[5][6]:

{x(t)=[y(t)]p1y(t)=[x(t)]p1x(0)=1y(0)=0

Where x corresponds to cqp(t) and y corresponds to sqp(t).[7]

Definition through analysis

The definition of sine and cosine through integrals can be extended to define the squigonometric functions. Let 1<p< and define a differentiable function Fp:[0,1] by:

Fp(x)=0x11tppdt

Since Fp is strictly increasing it is a one-to-one function on [0,1] with range [0,πp/2], where πp is defined as follows:

πp=20111tppdt

Let sqp be the inverse of Fp on [0,πp/2]. This function can be extended to [0,πp] by defining the following relationship:

sqp(x)=sqp(πpx)

By this means sqp is differentiable in and, corresponding to this, the function cqp is defined by:

cqp(x)=ddxsqp(x)

Tanquent, cotanquent, sequent and cosequent

The tanquent, cotanquent, sequent and cosequent functions can be defined as follows[8][9]:

tqp(t)=sqp(t)cqp(t)
ctqp(t)=cqp(t)sqp(t)
seqp(t)=1cqp(t)
cseqp(t)=1sqp(t)

Inverse squigonometric functions

General versions of the inverse squine and cosquine can be derived from the initial value problem above. Let x=cqp(y); by the inverse function rule, dxdy=[sqp(y)]p1=(1xp)(p1)/p. Solving for y gives the definition of the inverse cosquine:

y=cqp1(x)=x1(11tp)p1pdt

Similarly, the inverse squine is defined as:

sqp1(x)=0x(11tp)p1pdt

Applications

Solving integrals

Squigonometric substitution can be used to solve integrals, such as integrals in the generic form I=ab(1tp)1pdt.

References

  1. Poodiack , Robert D.  (April 2016 ). "Squigonometry, Hyperellipses, and Supereggs." Mathematics Magazine . 89  (2 ): 99-100 . doi:[1] Check |doi= value (help). Check date values in: |date= (help)
  2. Poodiack , Robert D.  (April 2016 ). "Squigonometry, Hyperellipses, and Supereggs." Mathematics Magazine . 89  (2 ): 100-101 . doi:[2] Check |doi= value (help). Check date values in: |date= (help)
  3. Poodiack, Robert D.; Wood, William E. (2022). Squigonometry: The Study of Imperfect Circles (1st ed.). Springer Nature Switzerland. p. 1. Search this book on
  4. Elbert, Á. (1987-09-01). "On the half-linear second order differential equations". Acta Mathematica Hungarica. 49 (3): 487–508. doi:10.1007/BF01951012. ISSN 1588-2632.
  5. Wood , William E. (October 2011 ). "Squigonometry". Mathematics Magazine . 84  (4 ): 264. doi:[3] Check |doi= value (help). Check date values in: |date= (help)
  6. Chebolu , Sunil; Hatfield, Andrew; Klette, Riley; Moore, Cristopher; Warden, Elizabeth (Fall 2022). "Trigonometric functions in the p-norm". BSU Undergraduate Mathematics Exchange. 16 (1): 4, 5. doi:[4] Check |doi= value (help).
  7. Girg , Petr E.; Kotrla, Lukáš (February 2014). Differentiability properties of p-trigonometric functions. p. 104. doi:[5] Check |doi= value (help). Search this book on
  8. Poodiack , Robert D.  (April 2016 ). "Squigonometry, Hyperellipses, and Supereggs." Mathematics Magazine . 89  (2 ): 96 . doi:[6] Check |doi= value (help). Check date values in: |date= (help)
  9. Edmunds , David E. ; Gurka, Petr; Lang, Jan (2012 ). "Properties of generalized trigonometric functions". Journal of Approximation Theory. 164  (1 ): 49 . doi:[7] Check |doi= value (help). Check date values in: |date= (help)

See also


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