[1]刘大学,殷广川,黄元浩.基于人机混合智能的无人平台设计[J].控制与信息技术(原大功率变流技术),2018,(06):27-31.[doi:10.13889/j.issn.2096-5427.2018.06.005]
 LIU Daxue,YIN Guangchun,HUANG Yuanhao.Design of Ground Unmanned Platform Based on Human-machine Hybrid Intelligence[J].High Power Converter Technology,2018,(06):27-31.[doi:10.13889/j.issn.2096-5427.2018.06.005]
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基于人机混合智能的无人平台设计()
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《控制与信息技术》(原《大功率变流技术》)[ISSN:2095-3631/CN:43-1486/U]

卷:
期数:
2018年06期
页码:
27-31
栏目:
控制理论与应用
出版日期:
2018-12-05

文章信息/Info

Title:
Design of Ground Unmanned Platform Based on Human-machine Hybrid Intelligence
文章编号:
2096-5427(2018)06-0027-05
作者:
刘大学 殷广川黄元浩
(国防科技大学,湖南 长沙 410073)
Author(s):
LIU DaxueYIN GuangchunHUANG Yuanhao
( National University of Defense Technology, Changsha, Hunan 410073,China )
关键词:
地面无人平台操控终端混合智能遥控
Keywords:
ground unmanned platform control terminal hybrid intelligence remote control
分类号:
V279
DOI:
10.13889/j.issn.2096-5427.2018.06.005
文献标志码:
A
摘要:
为了应对复杂的地面环境、多变的任务,提高地面无人平台的实用性,需要将人的智能引入到整个无人系统中,以应对对任务的高层理解,辅助无人系统感知、决策和控制;同时作为一个执行单元,无人系统需要从整体的角度将平台的移动能力与系统中相关要素进行整合,构建一体化的无人平台,而运动控制赋予了平台机动能力,拓展了任务载荷的工作范围,可提升整个系统的能力。本文讨论了基于人机混合智能的一体化体系结构,分析和讨论了平台的多种控制方式,并对整个系统的操控终端形式进行了初探。
Abstract:
In order to adapt to the complex ground environment, various tasks and improve the practicability of unmanned platform, it is necessary to introduce human intelligence into the whole system, apply human intelligence, high-level understanding of tasks, and assist the perception, decision-making and control of unmanned system. In addition, as an execution unit, the unmanned system needs to integrate the mobile capability of the platform with relevant elements of the system from an overall perspective to build an integrated unmanned system. Motion control enables the moving capacity and extends the working scope under mission load, and can efficiently enhance the system capacity. This paper discussed the integration architecture based on man-machine hybrid intelligence and under this guidance, analyzed and discusses various control modes of the platform, and finally made a preliminary exploration of the control terminal form of the whole system.

参考文献/References:

[1] 孙振平. 地面无人作战平台应用与发展[J]. 国防科技,2013,34 (5):12-16.
SUN Z P. The Principle and Development of Unmanned Ground Combat Vehicle[J]. National Defense Science & Technology,2013,34 (5):12-16.
[2] BRADY J . Cockroach-inspired robotics research opens new doors for missions[EB/ OL]. 2016-2-11[2018-08-10]. http://www.army mil/article/162328/cockroach inspiredrobotics-research-opens _ _new_ doors_for_missions.
[3] ZHANG R B,DUAN L Q,SHI C T. A method to evaluate autonomous performance for Unmanned Surface Vehicle[C]// Control Conference. Chengdu:IEEE, 2016:7104-7109.
[4]牛轶峰,沈林成,戴斌,等.无人作战系统发展[J].国防科技,2009,30(5):1-11.  
NIU Y F,SHEN L C,DAI P,et al. A Survey of Unmanned Combat System Development[J]. National Defense Science & Technology,2009, 30(5):1-11.
[5] 刘大学,宋金泽,聂祖国. 分级智能化的武器平台—无人平台体系结构解析[J]. 国防科技,2013,34 (5): 8-11.
 LIU D X, SONG J Z, NIE Z G. Leveled Intelligent Weapon Platform-Analyzing the Architecture of Unmanned Platform[J]. National Defense Science & Technology,2013,34 (5): 8-11.
[6] FAROOG W, KHAN M A, REHMAN S. AMVR: A multicast routing protocol for autonomous military vehicles communication in VANET[C] // International Bhurban Conference on Applied Sciencesand Technology. Pakistan, Islamabad: IEEE, 2017:699-706.
[7] 龚建伟,姜岩,徐威. 无人驾驶车辆模型预测控制[M]. 北京:北京理工大学出版社,2014.
[8] 修彩靖,陈慧. 基于混合体系结构的无人驾驶车辆系统[J].农业机械学报,2012, 43(1): 18-21.
XIU C J, CHEN H. Autonomous Vehicle System Based on Hybrid Architecture[J]. Transactions of the Chinese Society for Agricultural Machinery,2012, 43(1): 18-21.
[9] 孟红,朱森.地面无人系统的发展及未来趋势[J]. 兵工学报,2014 (s1): 1-7. MENG H, ZHU S. The Development and Future Trends of Unmanned Ground Systems[J].ACTA ARMAMENTARII,2014 (s1):1-7.
[10] 陈慧岩,熊光明,龚建伟. 无人驾驶车辆理论与设计[M].北京:北京理工大学出社,2018.

备注/Memo

备注/Memo:
收稿日期:2018-11-01
作者简介:刘大学(1978—),男,副研究员,主要研究方向为地面无人系统的规划控制、人机交互等。
基金项目:载人航天预研项目(060601)
更新日期/Last Update: 2018-12-25