Nonparametric estimation of the stationary density for Hawkes-diffusion systems with known and unknown intensity
Abstract
We investigate the nonparametric estimation problem of the density π, representing the stationary distribution of a two-dimensional system (Zt)t ∈[0, T]=(Xt, λt)t ∈[0, T]. In this system, X is a Hawkes-diffusion process, and λ denotes the stochastic intensity of the Hawkes process driving the jumps of X. Based on the continuous observation of a path of (Xt) over [0, T], and initially assuming that λ is known, we establish the convergence rate of a kernel estimator π(x*, y*) of π(x*,y*) as T → ∞. Interestingly, this rate depends on the value of y* influenced by the baseline parameter of the Hawkes intensity process. From the rate of convergence of π(x*,y*), we derive the rate of convergence for an estimator of the invariant density λ. Subsequently, we extend the study to the case where λ is unknown, plugging an estimator of λ in the kernel estimator and deducing new rates of convergence for the obtained estimator. The proofs establishing these convergence rates rely on probabilistic results that may hold independent interest. We introduce a Girsanov change of measure to transform the Hawkes process with intensity λ into a Poisson process with constant intensity. To achieve this, we extend a bound for the exponential moments for the Hawkes process, originally established in the stationary case, to the non-stationary case. Lastly, we conduct a numerical study to illustrate the obtained rates of convergence of our estimators.
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