Analyzing deviations of returning load from targeted landing point when space tether system is used

Xiaoye Xu; S. A. Ishkov; P. V. Faddeenkov; Changqing Wang

Analyzing deviations of returning load from targeted landing point when space tether system is used

Xiaoye Xu, S. A. Ishkov, P. V. Faddeenkov, Changqing Wang

School of Automation

Research output: Contribution to journal › Article › peer-review

Abstract

When tether system is used, we analyze the deviations, which are due to the errors of the deployment process of returning load from targeted landing point. We first give the mathematical model and calculation procedure of the whole processing, including: deployment of the tether line, free-swinging, cutting the tether line, entry into the atmosphere and eventually falling into zone surrounding the targeted landing point; next, in the absence of any error condition, we calculate the appropriate track position for beginning the release of tether line, so that the returning load can land on the targeted landing point; finally, when there is an error of orbital altitude, orbital eccentricity or the timing of tether line cutting, we calculate the range of deviation from the targeted landing point.

Original language	English
Pages (from-to)	294-298
Number of pages	5
Journal	Xibei Gongye Daxue Xuebao/Journal of Northwestern Polytechnical University
Volume	34
Issue number	2
State	Published - 1 Apr 2016

Keywords

Altitude control
Calculations
Computer simulation control
Dynamics
Error analysis
Mathematical models
Optimization
Orbit altitude
Orbit eccentricity
Orbits
Parametrization
Return load
Space tether
Tether lines
Timing of tether line cutting
Trajectory
Velocity

Cite this

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title = "Analyzing deviations of returning load from targeted landing point when space tether system is used",

abstract = "When tether system is used, we analyze the deviations, which are due to the errors of the deployment process of returning load from targeted landing point. We first give the mathematical model and calculation procedure of the whole processing, including: deployment of the tether line, free-swinging, cutting the tether line, entry into the atmosphere and eventually falling into zone surrounding the targeted landing point; next, in the absence of any error condition, we calculate the appropriate track position for beginning the release of tether line, so that the returning load can land on the targeted landing point; finally, when there is an error of orbital altitude, orbital eccentricity or the timing of tether line cutting, we calculate the range of deviation from the targeted landing point.",

keywords = "Altitude control, Calculations, Computer simulation control, Dynamics, Error analysis, Mathematical models, Optimization, Orbit altitude, Orbit eccentricity, Orbits, Parametrization, Return load, Space tether, Tether lines, Timing of tether line cutting, Trajectory, Velocity",

author = "Xiaoye Xu and Ishkov, {S. A.} and Faddeenkov, {P. V.} and Changqing Wang",

year = "2016",

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language = "英语",

volume = "34",

pages = "294--298",

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TY - JOUR

T1 - Analyzing deviations of returning load from targeted landing point when space tether system is used

AU - Xu, Xiaoye

AU - Ishkov, S. A.

AU - Faddeenkov, P. V.

AU - Wang, Changqing

PY - 2016/4/1

Y1 - 2016/4/1

N2 - When tether system is used, we analyze the deviations, which are due to the errors of the deployment process of returning load from targeted landing point. We first give the mathematical model and calculation procedure of the whole processing, including: deployment of the tether line, free-swinging, cutting the tether line, entry into the atmosphere and eventually falling into zone surrounding the targeted landing point; next, in the absence of any error condition, we calculate the appropriate track position for beginning the release of tether line, so that the returning load can land on the targeted landing point; finally, when there is an error of orbital altitude, orbital eccentricity or the timing of tether line cutting, we calculate the range of deviation from the targeted landing point.

AB - When tether system is used, we analyze the deviations, which are due to the errors of the deployment process of returning load from targeted landing point. We first give the mathematical model and calculation procedure of the whole processing, including: deployment of the tether line, free-swinging, cutting the tether line, entry into the atmosphere and eventually falling into zone surrounding the targeted landing point; next, in the absence of any error condition, we calculate the appropriate track position for beginning the release of tether line, so that the returning load can land on the targeted landing point; finally, when there is an error of orbital altitude, orbital eccentricity or the timing of tether line cutting, we calculate the range of deviation from the targeted landing point.

KW - Altitude control

KW - Calculations

KW - Computer simulation control

KW - Dynamics

KW - Error analysis

KW - Mathematical models

KW - Optimization

KW - Orbit altitude

KW - Orbit eccentricity

KW - Orbits

KW - Parametrization

KW - Return load

KW - Space tether

KW - Tether lines

KW - Timing of tether line cutting

KW - Trajectory

KW - Velocity

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M3 - 文章

AN - SCOPUS:84969135167

SN - 1000-2758

VL - 34

SP - 294

EP - 298

JO - Xibei Gongye Daxue Xuebao/Journal of Northwestern Polytechnical University

JF - Xibei Gongye Daxue Xuebao/Journal of Northwestern Polytechnical University

IS - 2

ER -

Analyzing deviations of returning load from targeted landing point when space tether system is used

Abstract

Keywords

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