Generalized VTD retrieval of atmospheric vortex kinematic structure. Part I: Formulation and error analysis

The primary circulation of atmospheric vortices, such as tropical cyclones and tornadoes, can be estimated from single-Doppler radar observations using the ground-based velocity track display (GBVTD) algorithm. The GBVTD algorithm has limitations in the following four areas: 1) distortion in the retrieved asymmetric wind fields, 2) a limited analysis domain, 3) the inability to resolve the cross-beam component of the mean wind, and 4) the inability to separate the asymmetric tangential and radial winds. This paper presents the generalized velocity track display (GVTD) algorithm, which eliminates the first two limitations inherent in the GBVTD technique and demonstrates the possibility of subjectively estimating the mean wind vector when its signature is visible beyond the influence of the vortex circulation. In this new paradigm, the GVTD algorithm fits the atmospheric vortex circulation to a new variable VdD/R-T in a linear azimuth angle (theta'), rather than the Doppler velocity V-d in a nonlinear angle (psi), which is used in GBVTD. Key vortex kinematic structures (e. g., mean wind, axisymmetric tangential wind, etc.) in the VdD/R-T space simplify the interpretation of the radar signature and eliminate the geometric distortion inherent in the V-d display. This is a significant improvement in diagnosing vortex structures in both operations and research. The advantages of using VdD/R-T are illustrated using analytical atmospheric vortices, and the properties are compared with GBVTD. The characteristics of the VdD/R-T display of Typhoon Gladys (1994) can be approximated by a constant mean wind plus an axisymmetric vortex.