Three-dimensional Brownian motion and the golden ratio rule

Abstract

Let X=(Xt)t0 be a transient diffusion process in (0,∞) with the diffusion coefficient σ>0 and the scale function L such that Xt→∞ as t→ ∞, let It denote its running minimum for t0, and let θ denote the time of its ultimate minimum I∞. Setting c(i,x)=1-2L(x)/L(i) we show that the stopping time \[τ*=∈f\t0 Xt f*(It)\\] minimizes E(θ-τ-θ) over all stopping times τ of X (with finite mean) where the optimal boundary f* can be characterized as the minimal solution to \[f'(i)=-σ2(f(i))L'(f(i))c(i,f(i))[L(f(i))-L(i)]∫if(i)ci'(i,y)[L(y) -L(i)]σ2(y)L'(y)\,dy\] staying strictly above the curve h(i)=L-1(L(i)/2) for i>0. In particular, when X is the radial part of three-dimensional Brownian motion, we find that \[τ *=∈f\t0Xt-ItIt\,\] where =(1+5)/2=1.61… is the golden ratio. The derived results are applied to problems of optimal trading in the presence of bubbles where we show that the golden ratio rule offers a rigorous optimality argument for the choice of the well-known golden retracement in technical analysis of asset prices.