Rand-inspired Non-mathematician Discovers Hypercomplex Numbers, with Possible Implications for Mathematics and the Philosophy of Science

I haven’t the foggiest idea whether this would bear scientific scrutiny, but he certainly deserves an A for creative self-promotion.
From a new press release which appears to have been authored by Atlasphere member Rodney Rawlings:

(PRLEAP.COM) A Toronto, Ontario, writer and editor has arrived at a system of creating hypercomplex numbersâ??numbers that extend the complex number system to more dimensionsâ??using only high school algebra, as viewed through the lens of Ayn Randâ??s philosophy of Objectivism. He contends that this has implications for mathematics and the philosophy of science.
Rodney Rawlings calls his multidimensional numbers â??RADN numbersâ?â??for â??rotating any-dimensional numbers,â? because they have a property of rotation exactly analogous to that of the complex numbers. They are also commutative and distributive like them.
He says that he arrived at this result by asking himself what exactly numbers are, how they arise in the human mind, and what their relationship to reality is. But these questions were only so fruitful because he used a correct philosophy, he claimsâ??Ayn Randâ??s. Any other philosophy, such as the currently influential one of Karl Popper, he says, would not have led to such a result. â??This has two implications: first, that Randâ??s philosophy has a strong element of truth, at least in the area of epistemology; and second, that the type of numbers I discovered must have a special significance, seeing as how they are intimately related to the basic nature of numbers.â?

â??All I set out to do was to understand, and perhaps explain, the complex numbers, which are two-dimensional, in a more concrete way,â? says Rawlings. â??Then, at one point, I realized that my reasoning might apply with equal force to three dimensions and beyond. When I finally turned to that question, I was led step by step to what I thought was a novel method for creating new systems.â?
Numbers of more than two dimensions are called â??hypercomplex numbers,â? and there are many types, developed over the past century or so. One of the most famous are the quaternionsâ??four-dimensional numbers developed by Irish genius William Rowan Hamilton that can be used to represent space and time, and have found a niche in 3D graphics applications. Quaternions, however, are only one result of the Cayley-Dickson construction, a â??programâ? that can be used to create systems of any dimensionality. And there are many types of such programs, for example â??hypernumbersâ? and â??multicomplex numbers.â?
Rawlings contends that the RADN program (which, he hastens to add, is not a new one but already known to mathematicians under a different name) must have a unique status among the hypercomplexes, because of the way he, a non-mathematician, arrived at them by means of extremely simple algebra absent any of the tools of modern analysis, but armed with a philosophy that takes a particular and unconventional view of the nature of concepts and of mathematics.
Accordingly, Rawlings decided to write up his thoughts and reasoning in an essay entitled â??Understanding Imaginaries Through Hidden Numbers,â? which he is currently offering at a low price on Lulu.com (go to www.lulu.com/content/750696).
He is hoping the essay will stimulate thought on the nature of mathematics, of addition and multiplication, of dimensions, of imaginary units, and of multidimensioned numbers, and lead to a fresh, and more positive, assessment of the ideas of Ayn Rand.
â??It remains to be seen whether my conjecture that this class of numbers has a unique status holds any water,â? says Rawlings. But, he adds, at the very least the mere fact that a layman, using Ayn Randâ??s philosophy, could invent on his own such an idea as hypercomplex numbers is worthy of note to anyone interested in the philosophy of science and mathematics.
Contact Information
R. Rawlings

I wonder what Objectivist philosopher-of-science Harry Binswanger would think.