Dynamic Modeling of Cable-Suspended Payload Quadcopter: A Physics-Informed Deep Learning Approach

Y. Y. Chan; Kam K.H. Ng; Ye Liu

doi:10.2514/6.2025-3242

Dynamic Modeling of Cable-Suspended Payload Quadcopter: A Physics-Informed Deep Learning Approach

Y. Y. Chan
, Kam K.H. Ng
, Ye Liu

Research output: Chapter in book / Conference proceeding › Conference article published in proceeding or book › Academic research › peer-review

Abstract

This paper introduces a novel methodology for modeling Cable-Suspended Payload Quad copters (CSPQs). Although cable-suspended systems offer significant operational advantages, they are characterized by increased modeling complexity arising from payload swing dynamics and intricate aerodynamic effects. To address these challenges, we propose a hybrid modelling framework that integrates physics-based modeling with deep learning techniques. Specifically, our approach employs a Physics-Informed Neural Network (PINN) architecture, leveraging an attention-enhanced Temporal Convolutional Network (PIATCN), in which the quad copterpay load dynamics are incorporated as a physics-informed regularization term. This framework is capable of capturing complex, nonlinear behaviors while ensuring physically consistent predictions and reducing the volume of required training data. The proposed method is evaluated by comparing its state prediction accuracy against several alternatives, including models based on first-principles physics, recurrent neural network architectures, and comparable data-driven models that do not incorporate physics-based regularization.

Original language	English
Title of host publication	AIAA AVIATION FORUM AND ASCEND, 2025
Publisher	American Institute of Aeronautics and Astronautics Inc. (AIAA)
ISBN (Print)	9781624107382
DOIs	https://doi.org/10.2514/6.2025-3242
Publication status	Published - Jul 2025
Event	AIAA AVIATION FORUM AND ASCEND, 2025 - Las Vegas, United States Duration: 21 Jul 2025 → 25 Jul 2025

Publication series

Name	AIAA Aviation Forum and ASCEND, 2025

Conference

Conference	AIAA AVIATION FORUM AND ASCEND, 2025
Country/Territory	United States
City	Las Vegas
Period	21/07/25 → 25/07/25

Keywords

Aerodynamic Coefficients
Data Acquisition
Data Driven Model
Dynamic Modelling
Eigen system Realization Algorithm
Kinetic Energy
Quadcopter
Recurrent Neural Network
Robots
State Transition Equation

ASJC Scopus subject areas

Space and Planetary Science
Energy Engineering and Power Technology
Nuclear Energy and Engineering
Aerospace Engineering

More information

10.2514/6.2025-3242

Cite this

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title = "Dynamic Modeling of Cable-Suspended Payload Quadcopter: A Physics-Informed Deep Learning Approach",

abstract = "This paper introduces a novel methodology for modeling Cable-Suspended Payload Quad copters (CSPQs). Although cable-suspended systems offer significant operational advantages, they are characterized by increased modeling complexity arising from payload swing dynamics and intricate aerodynamic effects. To address these challenges, we propose a hybrid modelling framework that integrates physics-based modeling with deep learning techniques. Specifically, our approach employs a Physics-Informed Neural Network (PINN) architecture, leveraging an attention-enhanced Temporal Convolutional Network (PIATCN), in which the quad copterpay load dynamics are incorporated as a physics-informed regularization term. This framework is capable of capturing complex, nonlinear behaviors while ensuring physically consistent predictions and reducing the volume of required training data. The proposed method is evaluated by comparing its state prediction accuracy against several alternatives, including models based on first-principles physics, recurrent neural network architectures, and comparable data-driven models that do not incorporate physics-based regularization.",

keywords = "Aerodynamic Coefficients, Data Acquisition, Data Driven Model, Dynamic Modelling, Eigen system Realization Algorithm, Kinetic Energy, Quadcopter, Recurrent Neural Network, Robots, State Transition Equation",

author = "Chan, \{Y. Y.\} and Ng, \{Kam K.H.\} and Ye Liu",

note = "Publisher Copyright: {\textcopyright} 2025 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved.; AIAA AVIATION FORUM AND ASCEND, 2025 ; Conference date: 21-07-2025 Through 25-07-2025",

year = "2025",

month = jul,

doi = "10.2514/6.2025-3242",

language = "English",

isbn = "9781624107382",

series = "AIAA Aviation Forum and ASCEND, 2025",

publisher = "American Institute of Aeronautics and Astronautics Inc. (AIAA)",

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address = "United States",

}

Chan, YY, Ng, KKH & Liu, Y 2025, Dynamic Modeling of Cable-Suspended Payload Quadcopter: A Physics-Informed Deep Learning Approach. in AIAA AVIATION FORUM AND ASCEND, 2025. AIAA Aviation Forum and ASCEND, 2025, American Institute of Aeronautics and Astronautics Inc. (AIAA), AIAA AVIATION FORUM AND ASCEND, 2025, Las Vegas, United States, 21/07/25. https://doi.org/10.2514/6.2025-3242

Dynamic Modeling of Cable-Suspended Payload Quadcopter: A Physics-Informed Deep Learning Approach. / Chan, Y. Y.; Ng, Kam K.H.; Liu, Ye.
AIAA AVIATION FORUM AND ASCEND, 2025. American Institute of Aeronautics and Astronautics Inc. (AIAA), 2025. (AIAA Aviation Forum and ASCEND, 2025).

Research output: Chapter in book / Conference proceeding › Conference article published in proceeding or book › Academic research › peer-review

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PY - 2025/7

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N2 - This paper introduces a novel methodology for modeling Cable-Suspended Payload Quad copters (CSPQs). Although cable-suspended systems offer significant operational advantages, they are characterized by increased modeling complexity arising from payload swing dynamics and intricate aerodynamic effects. To address these challenges, we propose a hybrid modelling framework that integrates physics-based modeling with deep learning techniques. Specifically, our approach employs a Physics-Informed Neural Network (PINN) architecture, leveraging an attention-enhanced Temporal Convolutional Network (PIATCN), in which the quad copterpay load dynamics are incorporated as a physics-informed regularization term. This framework is capable of capturing complex, nonlinear behaviors while ensuring physically consistent predictions and reducing the volume of required training data. The proposed method is evaluated by comparing its state prediction accuracy against several alternatives, including models based on first-principles physics, recurrent neural network architectures, and comparable data-driven models that do not incorporate physics-based regularization.

AB - This paper introduces a novel methodology for modeling Cable-Suspended Payload Quad copters (CSPQs). Although cable-suspended systems offer significant operational advantages, they are characterized by increased modeling complexity arising from payload swing dynamics and intricate aerodynamic effects. To address these challenges, we propose a hybrid modelling framework that integrates physics-based modeling with deep learning techniques. Specifically, our approach employs a Physics-Informed Neural Network (PINN) architecture, leveraging an attention-enhanced Temporal Convolutional Network (PIATCN), in which the quad copterpay load dynamics are incorporated as a physics-informed regularization term. This framework is capable of capturing complex, nonlinear behaviors while ensuring physically consistent predictions and reducing the volume of required training data. The proposed method is evaluated by comparing its state prediction accuracy against several alternatives, including models based on first-principles physics, recurrent neural network architectures, and comparable data-driven models that do not incorporate physics-based regularization.

KW - Aerodynamic Coefficients

KW - Data Acquisition

KW - Data Driven Model

KW - Dynamic Modelling

KW - Eigen system Realization Algorithm

KW - Kinetic Energy

KW - Quadcopter

KW - Recurrent Neural Network

KW - Robots

KW - State Transition Equation

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DO - 10.2514/6.2025-3242

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SN - 9781624107382

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BT - AIAA AVIATION FORUM AND ASCEND, 2025

PB - American Institute of Aeronautics and Astronautics Inc. (AIAA)

T2 - AIAA AVIATION FORUM AND ASCEND, 2025

Y2 - 21 July 2025 through 25 July 2025

ER -

Dynamic Modeling of Cable-Suspended Payload Quadcopter: A Physics-Informed Deep Learning Approach

Abstract

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Conference

Keywords

ASJC Scopus subject areas

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