Patent ID: 9102420
Filing Date: 2015-08-11
Classification: B64G

Abstract:
1. An orbit insertion device for an artificial satellite comprising an artificial satellite structure including a plurality of solar arrays, a plurality of propellant tanks, and a plurality of propulsion systems that forms a basic shape of the artificial satellite; a plurality of sensors for measuring a radial coordinate and an angular coordinate of the artificial satellite in a polar coordinate system with respect to a planetary center and sending them as a plurality of measured states that is a plurality of electrical signals representing a measured radial coordinate and a measured angular coordinate of the artificial satellite; and a plurality of thrusters for generating a thrust for propelling the artificial satellite to a target orbit, the orbit insertion device comprising: a planetary attraction constant estimator receiving the plurality of measured states, and calculating a planetary attraction constant, which is a product of a gravitational constant and a planetary mass, as a polynomial of the radial coordinate, a radial acceleration and an angular speed, where the radial acceleration is a second order time derivative of the radial coordinate; a drag force coefficient estimator receiving the plurality of measured states, and calculating a drag force coefficient, which is a drag force acting on the artificial satellite in radial direction with respect to the planetary center divided by a product of the planetary mass, an opposite sign of a radial speed and a squared radial speed, as a polynomial of the radial speed and a function of the radial coordinate monotonically decreasing with respect to increasing radial coordinate; a rate of convergence calculation unit receiving the drag force coefficient, and calculating a rate of convergence, with which the radial coordinate of the artificial satellite approaches to a radius of the target orbit, as a linear combination of the drag force coefficient divided by the radial speed and a small quantity that is a positive number smaller than an absolute value of the drag force coefficient divided by the radial speed; a fictitious control calculation unit receiving the planetary attraction constant, the drag force coefficient and the rate of convergence, and calculating a fictitious control, which is a centripetal acceleration required to propel the artificial satellite to the target orbit, as a linear combination of the planetary attraction constant divided by the radial coordinate squared, the drag force coefficient, a product of the rate of convergence and the radial speed, and a small quantity that is a positive number smaller than an absolute value of the planetary constant divided by the radial coordinate squared; and a normalized thrust calculation unit receiving the fictitious control, and calculating a normalized thrust, the thrust normalized with respect to a satellite mass, as a product of the radial coordinate and a first order time derivative of a square root of the fictitious control divided by the radial coordinate.