A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay

Alexander Domoshnitsky; Oleg Kupervasser; Hennadii Kutomanov; Roman Yavich

doi:10.1007/978-981-16-6297-3_4

A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay

Alexander Domoshnitsky, Oleg Kupervasser, Hennadii Kutomanov, Roman Yavich

Department of Mathematics

Ariel University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The paper addresses the problem of visual navigation of ground robots using a camera positioned at a certain elevation above the confined area. Also, the methods of the stability theory of delay differential equations are used in the study of an actual engineering problem of a ground robot autonomous path. We give a description of autopilot for the stabilization of the ground robot autonomous motion according to desirable path. Indeed, large time delay exists in obtaining by autopilot current information about robot position and orientation, because of big data processing by vision-based (visual) navigation system. Despite this fact, we can prove that autopilot can guarantee a stable desirable path. We demonstrate how to create an appropriate controlling signal for the described information time delay and calculate control parameters for case of polygonal chain path. This path consists of linear motion along with line segments and rotations in vertices.

Original language	English
Title of host publication	Functional Differential Equations and Applications - FDEA-2019
Editors	Alexander Domoshnitsky, Alexander Rasin, Seshadev Padhi
Pages	49-70
Number of pages	22
DOIs	https://doi.org/10.1007/978-981-16-6297-3_4
State	Published - 2021
Event	7th International Conference on Functional Differential Equations and Applications, FDEA 2019 - Ariel, Israel Duration: 22 Aug 2019 → 27 Aug 2019

Publication series

Name	Springer Proceedings in Mathematics and Statistics
Volume	379

Conference

Conference	7th International Conference on Functional Differential Equations and Applications, FDEA 2019
Country/Territory	Israel
City	Ariel
Period	22/08/19 → 27/08/19

Keywords

Airborne control
Autopilot
Differential equations
Ground robots
Stability
Tethered platform
Time delay
Vision-based navigation
Visual navigation

All Science Journal Classification (ASJC) codes

General Mathematics

Access to Document

10.1007/978-981-16-6297-3_4

Cite this

Domoshnitsky, A., Kupervasser, O., Kutomanov, H., & Yavich, R. (2021). A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay. In A. Domoshnitsky, A. Rasin, & S. Padhi (Eds.), Functional Differential Equations and Applications - FDEA-2019 (pp. 49-70). (Springer Proceedings in Mathematics and Statistics; Vol. 379). https://doi.org/10.1007/978-981-16-6297-3_4

Domoshnitsky, Alexander ; Kupervasser, Oleg ; Kutomanov, Hennadii et al. / A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay. Functional Differential Equations and Applications - FDEA-2019. editor / Alexander Domoshnitsky ; Alexander Rasin ; Seshadev Padhi. 2021. pp. 49-70 (Springer Proceedings in Mathematics and Statistics).

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title = "A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay",

abstract = "The paper addresses the problem of visual navigation of ground robots using a camera positioned at a certain elevation above the confined area. Also, the methods of the stability theory of delay differential equations are used in the study of an actual engineering problem of a ground robot autonomous path. We give a description of autopilot for the stabilization of the ground robot autonomous motion according to desirable path. Indeed, large time delay exists in obtaining by autopilot current information about robot position and orientation, because of big data processing by vision-based (visual) navigation system. Despite this fact, we can prove that autopilot can guarantee a stable desirable path. We demonstrate how to create an appropriate controlling signal for the described information time delay and calculate control parameters for case of polygonal chain path. This path consists of linear motion along with line segments and rotations in vertices.",

keywords = "Airborne control, Autopilot, Differential equations, Ground robots, Stability, Tethered platform, Time delay, Vision-based navigation, Visual navigation",

author = "Alexander Domoshnitsky and Oleg Kupervasser and Hennadii Kutomanov and Roman Yavich",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd.; 7th International Conference on Functional Differential Equations and Applications, FDEA 2019 ; Conference date: 22-08-2019 Through 27-08-2019",

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doi = "10.1007/978-981-16-6297-3_4",

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Domoshnitsky, A , Kupervasser, O, Kutomanov, H & Yavich, R 2021, A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay. in A Domoshnitsky, A Rasin & S Padhi (eds), Functional Differential Equations and Applications - FDEA-2019. Springer Proceedings in Mathematics and Statistics, vol. 379, pp. 49-70, 7th International Conference on Functional Differential Equations and Applications, FDEA 2019, Ariel, Israel, 22/08/19. https://doi.org/10.1007/978-981-16-6297-3_4

A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay. / Domoshnitsky, Alexander ; Kupervasser, Oleg; Kutomanov, Hennadii et al.
Functional Differential Equations and Applications - FDEA-2019. ed. / Alexander Domoshnitsky; Alexander Rasin; Seshadev Padhi. 2021. p. 49-70 (Springer Proceedings in Mathematics and Statistics; Vol. 379).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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A Method for Stabilization of Ground Robot Path Controlled by Airborne Autopilot with Time Delay

Abstract

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Conference

Keywords

All Science Journal Classification (ASJC) codes

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