Time-of-flight estimation by utilizing Kalman filter tracking information -- Part I: the concept

Abstract

Recent detector concepts at future linear or circular e- e+ colliders emphasize the benefits of time-of-flight measurements for particle identification of long-lived charged hadrons. That method relies on a precise estimation of the time-of-flight as expected, for a given mass hypothesis, from the reconstructed particle momentum and its trajectory. We show that for a realistic detector set-up, relativistic formulae are a good approximation down to lowest possible momenta. The optimally fitted track parameters are commonly defined near the interaction region. Extrapolation to a time-of-flight counter located behind the central tracking device can usually only be performed by a track model undisturbed from material effects. However, the true trajectory is distorted by multiple Coulomb scattering and the momentum is changed by energy loss. As a consequence, the estimated time-of-flight is biased by a large systematic error. This study presents a novel approach of time-of-flight estimation by splitting the trajectory into a chain of undisturbed track elements, following as close as possible the true trajectory. Each track element possesses an individual momentum pi and flight distance li. Remarkably, our formulae emerge by formally replacing the global momentum squared p2 by the weighted harmonic mean of the individual \ pi2 \, with the weights being the corresponding individual \ li \. The optimally fitted parameters of the individual track elements can be obtained from track reconstruction by a Kalman filter plus smoother. However, care must be taken when including mass-dependent material effects. Explicit formulae for a simple scenario (homogeneous magnetic field and cylindrical surfaces) are given, together with an overview about the treatment of multiple Coulomb scattering and energy loss by a Kalman filter.