Asymmetrical Primitive Centrifuge Configurations and Vanishing Sums of Roots of Unity

Sunday, 5 March 2023

A centrifuge has some fixed number of positions into each of which a sample may be loaded. Equal-weight samples must be placed so that they’re perfectly balanced.

In the attached article, I present an asymmetric balanced irreducible centrifuge configuration, and relate configurations to sums of roots of unity.

PDF article:
centrifuge.pdf

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On Badly Balanced Centrifuge Configurations

Monday, 27 February 2023

A high-speed centrifuge can be so sensitive to balance that you should weigh the samples to ensure that they are equal (within tolerance), and load them symmetrically, or in symmetrical combination.

In a certain manufacturer’s instructions for their 24-position centrifuge, configurations were suggested for 5 on 7 samples. These seemed dangerously out of balance to me.

I discuss this in the attached article.

PDF article:
centrifuge-imbalance.pdf

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Frustum Formulae

Monday, 27 February 2023

In the attached article, we generalise the Heronian mean, and discover that this behaves as a logarithmic mean in the limit.

PDF article:
frustum-formulae.pdf

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On the Visualisation of Inequalities amongst Homogeneous Means

Monday, 27 February 2023

In the attached article, I show how the relationships between binary means might be illustrated.

I describe ‘distillation’, which is composed of ‘reduction’ and ‘compression’.

I include plots for

  • arithmetic mean
  • geometric mean
  • harmonic mean
  • contraharmonic mean
  • quadratic mean
  • Heronian mean
  • logarithmic mean
  • first and second Seiffert means
  • Neuman–Sándor mean
  • power means
  • Lehmer means
  • Stolarsky means

and a few others.

PDF article:
mean-inequal-vis.pdf

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On a Connection between the Birthday Puzzles

Sunday, 5 February 2023

The first birthday puzzle asks: How many people need to be gathered together in order that there is an at-least evens chance of a birthday coincidence? The answer is just 23.

We might write this

\displaystyle B_1(365, 0.5) = 23

The second birthday puzzle asks: How many other people need to be gathered together in order that there is an at-least evens chance of a coincidence with your birthday? The answer is 253.

Notice that

\displaystyle \binom{23}{2} = 253

It turns out that this is not a coincidence.

The value of the first birthday puzzle is awkward to calculate. In the attached article, I show how the above binomial connection leads to a good closed-form approximation for the first birthday problem:

\displaystyle \widehat{B_1}(n, p) = \frac{\sqrt{8 \frac{\ln (1 - p)}{\ln \left( 1 - \frac{1}{n} \right)} + 1} + 1}{2}

PDF article:
birthday-puzzle-connection.pdf

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Indeterminate Forms and L’Hôpital’s Rule

Wednesday, 8 September 2021

Introduction

In an earlier article, I showed how to prove that P_0=G, i.e. the zero power mean is the geometric mean, using L’Hôpital’s rule. It was also necessary to perform some transformations on a limit expression to allow L’Hôpital’s rule to be applied.

In this article, I show how this and various other common indeterminate forms may be transformed so that L’Hôpital’s rule may similarly be applied.

I also provide a table of the results of the derivations (or ‘differentiations’) for each case, as a useful reference.

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P₀(x,y) = G(x,y)

Saturday, 4 September 2021

Introduction

In my previous post, I showed why

\displaystyle P_0(X) = G(X)

that is, why

\displaystyle \lim_{k \to 0} \left( \frac{ \sum_{x \in X} x^k }{|X|} \right)^{\frac{1}{k}} = { \left( \, \prod_{x \in X} x \right) }^{\frac{1}{|X|}} = \sqrt[|X|]{ \prod_{x \in X} x }

Here, I repeat the exercise for the simpler case where X has just 2 members. I.e.

\displaystyle P_0(x,y) = G(x,y)

i.e.

\displaystyle \lim_{k \to 0} \left( \frac{ x^k + y^k }{2} \right)^{\frac{1}{k}} = { \left( x y \right) }^{\frac{1}{2}} = \sqrt{ x y }

Therefore this is just a special case of what was discussed in the previous post, but which may be somewhat easier to follow.
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P₀ = G

Friday, 3 September 2021

Introduction

Recently, I wished to understand why the zero-power mean is the geometric mean

\displaystyle P_0 = G

that is, why

\displaystyle \lim_{k \to 0} \left( \frac{ \sum_{x \in X} x^k }{|X|} \right)^{\frac{1}{k}} = { \left( \, \prod_{x \in X} x \right) }^{\frac{1}{|X|}} = \sqrt[|X|]{ \prod_{x \in X} x }

and this sent me on much more of a mathematical adventure than I expected, involving learning about evaluating limits, L’Hôpital’s rule, and about indeterminate forms and their transformations.
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On the Geometry of Hypertetrahedral Slices

Friday, 27 August 2021

The full article is attached as a PDF; please see the link at the end of this post.

Abstract

In this article, I investigate the (regular) hypertetrahedra and their measures, and orthogonal slices (or sections) through them.

I consider how to configure the vertices in order easily to calculate the measure.

Formulae are found for the distance between opposing facets of a hypertetrahedron, and I investigate the behaviour of these as the dimension increases.

I discuss the “shape” of slices through hypertetrahedra, showing these to be Cartesian products of hypertetrahedra of lower dimension. Then I briefly investigate slices through slices.

Formulae are found for the measure of a hypertetrahedron as an integral over (measures of) slices. From these, I find recurrence formulae, and from these, in turn, I find a closed form for the measure of a hypertetrahedron.

For example:
the measure (length) of the 1-dimensional hypertetrahedron of unit edge, which is just the unit line segment, is 1; for 2-dimensional, which is just the equilateral triangle, the measure (area) is \sqrt{3}/4; for 3-dimensional, which is the regular tetrahedron, the measure (capacity or volume) is \sqrt{2}/12; and so on.

I determine when (i.e. for which dimensions) the measure of a hypertetrahedron is rational, and show that when it is rational, it is in fact a unit fraction.

For example:
the measures of the 7- and 8-dimensional hypertetrahedra of unit edge are, respectively, 1/20160 and 1/215040. The value is also rational in dimensions 17 and 24.

The sequence of dimensions for such rational measures begins

\displaystyle 0, 1, 7, 8, 17, 24, 31, 48, 49, 71, 80, 97, \dots

Finally, I briefly investigate the behaviour of the discrete analogue of hypertetrahedra, i.e. hypertetrahedral numbers.

The article includes some tables of calculated values.
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A Survey of Methods for the Evaluation of Sums of Powers

Saturday, 21 August 2021

The full article (over 100 pages) is attached as a PDF; please see the link at the end of this post.

Abstract

The simple series

\displaystyle \sum_{m=1}^{n} m^k ,

where k and n are non-negative integers, is a sum of powers

\displaystyle 1^k + 2^k + 3^k + \cdots + (n-1)^k + n^k

We regard k as being fixed and relatively small, and n as being variable and potentially very large. That is, n \gg k.

Sometimes, we also denote this series by s_k(n) or by \sum n^k.

Such series may be expanded in closed form as polynomials.

Given the expression

\displaystyle \sum n^k

for some chosen k, we wish to re-express it as a polynomial

\displaystyle a_{k+1} n^{k+1} + a_k n^k + a_{k-1} n^{k-1} + \cdots + a_2 n^2 + a_1 n + a_0

Consider, for example,

\displaystyle s_5(n) = \sum_{m=1}^{n} m^5 = 1^5 + 2^5 + 3^5 + \cdots + (n-1)^5 + n^5

When n=1 000 000 (i.e. one million), we have

\displaystyle s_5(1 000 000) = 1^5 + 2^5 + 3^5 + \cdots + 999 999^5 + 1 000 000^5

This is fairly tedious to evaluate. But we can use any of various techniques to establish that

\displaystyle s_5(n) = \frac{1}{6} n^6 + \frac{1}{2} n^5 + \frac{5}{12} n^4 - \frac{1}{12} n^2

Now, rather than having 1 000 000 terms to sum, we have just 4 terms. So

\displaystyle s_5(1 000 000) = \frac{1}{6} \, 1 000 000^6 + \frac{1}{2} \, 1 000 000^5 + \frac{5}{12} \, 1 000 000^4 - \frac{1}{12} \, 1 000 000^2

which can quickly be evaluated as

\displaystyle s_5(1 000 000) = 166 667 166 667 083 333 333 333 250 000 000 000

Our example’s coefficients are

\displaystyle \langle a_j \rangle = \left< 0, 0, -\dfrac{1}{12}, 0, +\dfrac{5}{12}, +\dfrac{1}{2}, +\dfrac{1}{6} \right>

As we consider different values for k, the coefficients of these polynomials exhibit some remarkably and unexpectedly complicated behaviour. They seem rather erratic, following no obvious pattern. Likewise, the factors exhibit no obvious pattern, and indeed are not even always real.

Mathematicians have been studying these series for hundreds of years. There are many approaches; some old, and some very recent. The approaches are quite varied. In this article, I present the many approaches I have found in the literature and online.

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