System and Mathematical Modeling of Quadrotor Dynamics

被引:2
|
作者
Goodman, Jacob M. [1 ]
Kim, Jinho [1 ]
Gadsden, S. Andrew [1 ]
Wilkerson, Stephen A. [2 ]
机构
[1] Univ Maryland, Baltimore Cty UMBC, Baltimore, MD 21250 USA
[2] US Army Res Lab, Aberdeen, MD 21001 USA
来源
UNMANNED SYSTEMS TECHNOLOGY XVII | 2015年 / 9468卷
关键词
Multirotor; quadrotor; quadcopter; modeling; control; UAV; blade flapping;
D O I
10.1117/12.2185196
中图分类号
TP18 [人工智能理论];
学科分类号
081104 ; 0812 ; 0835 ; 1405 ;
摘要
Unmanned aerial systems (UAS) are becoming increasingly visible in our daily lives; and range in operation from search and rescue, monitoring hazardous environments, and to the delivery of goods. One of the most popular UAS are based on a quad-rotor design. These are typically small devices that rely on four propellers for lift and movement. Quad-rotors are inherently unstable, and rely on advanced control methodologies to keep them operating safely and behaving in a predictable and desirable manner. The control of these devices can be enhanced and improved by making use of an accurate dynamic model. In this paper, we examine a simple quadrotor model, and note some of the additional dynamic considerations that were left out. We then compare simulation results of the simple model with that of another comprehensive model.
引用
收藏
页数:11
相关论文
共 50 条
  • [1] Modeling of quadrotor helicopter dynamics
    Amir, M. Yasir
    Abbass, Valiuddin
    2008 INTERNATIONAL CONFERENCE ON SMART MANUFACTURING APPLICATION, 2008, : 100 - 105
  • [2] Mathematical Modeling and Analysis of a Quadrotor with Tilting Propellers
    Ji, Ruihang
    Ma, Jie
    2018 37TH CHINESE CONTROL CONFERENCE (CCC), 2018, : 1718 - 1722
  • [3] Mathematical Modelling and Identification of a Quadrotor
    Cardenas R, Cesar A.
    Collazos Morales, Carlos Andres
    Ospina, Juan P.
    Sanchez, Joaquin F.
    Caro-Ruiz, Claudia
    Hugo Grisales, Victor
    Ariza-Colpas, Paola
    De-la-Hoz-Franco, Emiro
    Gonzalez, Ramon E. R.
    COMPUTATIONAL SCIENCE AND ITS APPLICATIONS - ICCSA 2020, PT I, 2020, 12249 : 261 - 275
  • [4] Stability Analysis of Quadrotor using State Space Mathematical Modeling
    Vanitha, N. Suthanthira
    Manivannan, L.
    Meenakshi, T.
    Radhika, K.
    MATERIALS TODAY-PROCEEDINGS, 2020, 33 : 4040 - 4043
  • [5] Mathematical & Physical Modelling of a Quadrotor UAV
    Idrissi, Moad
    Annaz, Fawaz
    Salami, Mohammad
    2021 7TH INTERNATIONAL CONFERENCE ON CONTROL, AUTOMATION AND ROBOTICS (ICCAR), 2021, : 206 - 212
  • [6] Neural Network Modeling and Backstepping Control for Quadrotor
    Yu, Xinglin
    Lv, Zongyang
    Wu, Yuhu
    Sun, Xi-Ming
    2018 CHINESE AUTOMATION CONGRESS (CAC), 2018, : 3649 - 3654
  • [7] The tilt-quadrotor: concept, modeling and identification
    Moutinho, Alexandra
    Mateos, Estanislao
    Cunha, Filipe
    2015 IEEE INTERNATIONAL CONFERENCE ON AUTONOMOUS ROBOT SYSTEMS AND COMPETITIONS (ICARSC), 2015, : 156 - 161
  • [8] Modeling and Identification of Quadrotor Dynamics affected by Wind Stress
    Wi, Yejin
    Cescon, Marzia
    IFAC PAPERSONLINE, 2024, 58 (28): : 7 - 12
  • [9] QUADROTOR CONTROL SYSTEM FOR EDUCATION AND RESEARCH
    Gageik, Nils
    Montenegro, Sergio
    INTED2016: 10TH INTERNATIONAL TECHNOLOGY, EDUCATION AND DEVELOPMENT CONFERENCE, 2016, : 8259 - 8264
  • [10] Modeling and Robust Attitude Control of a Quadrotor System
    Torres Gaitan, Angelica
    Bolea, Yolanda
    2013 10TH INTERNATIONAL CONFERENCE ON ELECTRICAL ENGINEERING, COMPUTING SCIENCE AND AUTOMATIC CONTROL (CCE), 2013, : 7 - 12
12345