An analytic solution to the hypersonic, radiative blunt body problem

Two reduced forms of the Euler equations which allow spatial marching in subsonic flow regions are investigated for solving the inviscid blunt body problem. An analysis of the eignevalues to determine the properties of the steady and unsteady forms of the governing equations is performed. The steady

Three-body Faddeev equations in the Noyes-Fiedeldey form are rewritten as a matrix analog of a one-dimensional nonrelativistic SchrGdinger equation. Unlike the method of K-harmonics, where a similar equation was obtained by expansion of a three-body Schrijdinger equation wavefunction into the orthog

The problem of the chemically equilibrium three-dimensional boundary layer on a blunt body which is in motion in the atmosphere is considered. A solution of the system of equations of the boundary layer is found by the method of successive approximations, and simple analytic expressions are written

This paper considers the problem of precautionary savings for an expected utility specification with finite horizon. The exact solution is known for only a few cases. Numerical methods have limited applications because of Bellman's 'curse of dimensionality'. This paper derives a simple analytical ap

The problem of the optimal control of the rotation of an axisymmetric rigid body is investigated. An integral functional, characterizing the power consumption to carry out a manoeuvre is chosen as the criterion, and the boundary conditions for the angular velocity vector are arbitrary. The principal