I’m interested in working abroad in S.E. Asia, including Vietnam and Thailand where some researchers follow my blog, and in Europe or Israel, particularly along the Mediterranean but including Portugal. Please let me know if you feel that my talents and your needs might overlap.
This is a temporary pedagogical post of an elementary computation of a centroid required in an application to a potential employer.
This is a temporary pedagogical entry of a simple vector triple product calculation required in an application to a potential employer.
Each of the two scutoids depicted below contain 2-D examples of my two favorite families of convex polytopes–the permutahedra (the hexagon) and associahedra (the pentagon, also the 2-D stellahedron, OEIS A248727), related to multiplicative (OEIS A133314) and compositional (OEIS A133437) inversion of functions (or formal generating series), respectively.
(From “Scientists Have Discovered an Entirely New Shape, And It Was Hiding in Your Cells“)
Referring to week 299 of John Baez’s old blog or the Pre-Lie Algebra entry of nLab, a left pre-Lie algebra satisfies the associative relation, (AR),
To see the relation to Cayley’s work of 1857 as described in my pdf Mathemagical Forests (MF), let the generators be represented by the vectors (infinitesimal Lie generators) 
In MF, initially the op 
The resulting action of each side of the AR can be represented by a rooted tree with three nodes, or vertices, with two leaves and one root. 
(1) Arthur Cayley, On the theory of the analytical forms called trees, Phil. Mag. 13 (1857), 172-176.
(2) An N-Category Cafe posting by Baez on week 299 and pre-Lie algebras
(4) Butcher series: A story of rooted trees and numerical methods for evolution equations by McLachlan, Modin, Munthe-Kaas, and Verdier
(5) Combinatorial Hopf algebras by Loday and Ronco (Pg. 28 has a description of a pre-Lie product in terms of nonplanar unreduced trees, and pg. 18, a bijection between planar binary (PB) and planar unreduced trees (PUT) that might be useful in translating between arguments made using one formulation into the other. )
Given a compositional inverse pair 
with 
Then the associated formal group law (FGL) may be expressed as
![FGL(x,y) = f[f^{-1}(x)+f^{-1}(y)] = e^{a.[f^{-1}(x)+f^{-1}(y)]}](https://s0.wp.com/latex.php?latex=FGL%28x%2Cy%29+%3D+f%5Bf%5E%7B-1%7D%28x%29%2Bf%5E%7B-1%7D%28y%29%5D+%3D+e%5E%7Ba.%5Bf%5E%7B-1%7D%28x%29%2Bf%5E%7B-1%7D%28y%29%5D%7D&bg=ffffff&fg=333333&s=0 "FGL(x,y) = f[f^{-1}(x)+f^{-1}(y)] = e^{a.[f^{-1}(x)+f^{-1}(y)]}")
![= e^{a. D_t}|_{t=0} \;\; e^{t[f^{-1}(x)+f^{-1}(y)]}](https://s0.wp.com/latex.php?latex=%3D+e%5E%7Ba.+D_t%7D%7C_%7Bt%3D0%7D+%5C%3B%5C%3B+e%5E%7Bt%5Bf%5E%7B-1%7D%28x%29%2Bf%5E%7B-1%7D%28y%29%5D%7D&bg=ffffff&fg=333333&s=0 "= e^{a. D_t}|_{t=0} \;\; e^{t[f^{-1}(x)+f^{-1}(y)]}")
![= f(D_t)|_{t=0} \;\; e^{t[f^{-1}(x)+f^{-1}(y)]}](https://s0.wp.com/latex.php?latex=%3D+f%28D_t%29%7C_%7Bt%3D0%7D+%5C%3B%5C%3B+e%5E%7Bt%5Bf%5E%7B-1%7D%28x%29%2Bf%5E%7B-1%7D%28y%29%5D%7D&bg=ffffff&fg=333333&s=0 "= f(D_t)|_{t=0} \;\; e^{t[f^{-1}(x)+f^{-1}(y)]}")
