Component-wise dimensionally reduced flows with local models

Component-wise dimensionally reduced flows (CWDRFs) are characterized by the uniformly (over space and time) vanishing of some component(s) in the velocity gradient tensor, and they may present in various situations with different conditions. A more universal method for specifying and computing barotropic CWDRFs associated to the Navier-Stokes equation is designed for situations besides that in a (cyclic) box. The method is \textit{local} in the sense that global relations involving volume integration are not used, and the enthalpy gradient is used as the primitive variable and computed directly. Such a local method is more useful for, say, testing the physical relevance of CWDRFs, including the real Schur flows proposed recently, or finding their practically meaningful realizations. The local and global methods are shown to be equivalent for CWDRFs in (cyclic) boxes.