Quantum-Based Creative Generation Method for a Dancing Robot

In this paper, we propose a creative generation process model based on the quantum modeling simulation method. This model is mainly aimed at generating the running trajectory of a dancing robot and the execution plan of the dancing action. First, we used digital twin technology to establish data map...

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Main Authors: Peng Mei, GangYi Ding, QianKun Jin, FuQuan Zhang, YangFan Jiao
Format: Article
Language:English
Published: Frontiers Media S.A. 2020-12-01
Series:Frontiers in Neurorobotics
Subjects:
Online Access:https://www.frontiersin.org/articles/10.3389/fnbot.2020.559366/full
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spelling doaj-9b2a7309ea7f40de8ba01c93973ac5b32020-12-08T08:38:06ZengFrontiers Media S.A.Frontiers in Neurorobotics1662-52182020-12-011410.3389/fnbot.2020.559366559366Quantum-Based Creative Generation Method for a Dancing RobotPeng Mei0GangYi Ding1QianKun Jin2FuQuan Zhang3YangFan Jiao4Digital Performance and Simulation Technology, School of Computer Science & Technology, Beijing Institute of Technology, Beijing, ChinaDigital Performance and Simulation Technology, School of Computer Science & Technology, Beijing Institute of Technology, Beijing, ChinaDigital Performance and Simulation Technology, School of Computer Science & Technology, Beijing Institute of Technology, Beijing, ChinaFujian Provincial Key Laboratory of Information Processing and Intelligent Control, Minjiang University, Fuzhou, ChinaBeijing Wanshide Technology Co., Ltd., Beijing, ChinaIn this paper, we propose a creative generation process model based on the quantum modeling simulation method. This model is mainly aimed at generating the running trajectory of a dancing robot and the execution plan of the dancing action. First, we used digital twin technology to establish data mapping between the robot and the computer simulation environment to realize intelligent controllability of the robot's trajectory and the dance movements described in this paper. Second, we conducted many experiments and carried out a lot of research into information retrieval, information fidelity, and result evaluation. We constructed a multilevel three-dimensional spatial quantum knowledge map (M-3DQKG) based on the coherence and entangled states of quantum modeling and simulation. Combined with dance videos, we used regions with convolutional neural networks (R-CNNs) to extract character bones and movement features to form a movement library. We used M-3DQKG to quickly retrieve information from the knowledge base, action library, and database, and then the system generated action models through a holistically nested edge detection (HED) network. The system then rendered scenes that matched the actions through generative adversarial networks (GANs). Finally, the scene and dance movements were integrated, and the creative generation process was completed. This paper also proposes the creativity generation coefficient as a means of evaluating the results of the creative process, combined with artificial brain electroenchalographic data to assist in evaluating the degree of agreement between creativity and needs. This paper aims to realize the automation and intelligence of the creative generation process and improve the creative generation effect and usability of dance movements. Experiments show that this paper has significantly improved the efficiency of knowledge retrieval and the accuracy of knowledge acquisition, and can generate unique and practical dance moves. The robot's trajectory is novel and changeable, and can meet the needs of dance performances in different scenes. The creative generation process of dancing robots combined with deep learning and quantum technology is a required field for future development, and could provide a considerable boost to the progress of human society.https://www.frontiersin.org/articles/10.3389/fnbot.2020.559366/fullcreative generationquantum simulationinformation fidelityM-3DQKGQGANrobot trajectory
collection DOAJ
language English
format Article
sources DOAJ
author Peng Mei
GangYi Ding
QianKun Jin
FuQuan Zhang
YangFan Jiao
spellingShingle Peng Mei
GangYi Ding
QianKun Jin
FuQuan Zhang
YangFan Jiao
Quantum-Based Creative Generation Method for a Dancing Robot
Frontiers in Neurorobotics
creative generation
quantum simulation
information fidelity
M-3DQKG
QGAN
robot trajectory
author_facet Peng Mei
GangYi Ding
QianKun Jin
FuQuan Zhang
YangFan Jiao
author_sort Peng Mei
title Quantum-Based Creative Generation Method for a Dancing Robot
title_short Quantum-Based Creative Generation Method for a Dancing Robot
title_full Quantum-Based Creative Generation Method for a Dancing Robot
title_fullStr Quantum-Based Creative Generation Method for a Dancing Robot
title_full_unstemmed Quantum-Based Creative Generation Method for a Dancing Robot
title_sort quantum-based creative generation method for a dancing robot
publisher Frontiers Media S.A.
series Frontiers in Neurorobotics
issn 1662-5218
publishDate 2020-12-01
description In this paper, we propose a creative generation process model based on the quantum modeling simulation method. This model is mainly aimed at generating the running trajectory of a dancing robot and the execution plan of the dancing action. First, we used digital twin technology to establish data mapping between the robot and the computer simulation environment to realize intelligent controllability of the robot's trajectory and the dance movements described in this paper. Second, we conducted many experiments and carried out a lot of research into information retrieval, information fidelity, and result evaluation. We constructed a multilevel three-dimensional spatial quantum knowledge map (M-3DQKG) based on the coherence and entangled states of quantum modeling and simulation. Combined with dance videos, we used regions with convolutional neural networks (R-CNNs) to extract character bones and movement features to form a movement library. We used M-3DQKG to quickly retrieve information from the knowledge base, action library, and database, and then the system generated action models through a holistically nested edge detection (HED) network. The system then rendered scenes that matched the actions through generative adversarial networks (GANs). Finally, the scene and dance movements were integrated, and the creative generation process was completed. This paper also proposes the creativity generation coefficient as a means of evaluating the results of the creative process, combined with artificial brain electroenchalographic data to assist in evaluating the degree of agreement between creativity and needs. This paper aims to realize the automation and intelligence of the creative generation process and improve the creative generation effect and usability of dance movements. Experiments show that this paper has significantly improved the efficiency of knowledge retrieval and the accuracy of knowledge acquisition, and can generate unique and practical dance moves. The robot's trajectory is novel and changeable, and can meet the needs of dance performances in different scenes. The creative generation process of dancing robots combined with deep learning and quantum technology is a required field for future development, and could provide a considerable boost to the progress of human society.
topic creative generation
quantum simulation
information fidelity
M-3DQKG
QGAN
robot trajectory
url https://www.frontiersin.org/articles/10.3389/fnbot.2020.559366/full
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