Archive for 2007
A PAWL for Enhancing Strength and Endurance during Walking Using Interaction Force and Dynamical Information
- Тип контента: Научная статья
- Номер документа: 7122
- Название документа: A PAWL for Enhancing Strength and Endurance during Walking Using Interaction Force and Dynamical Information
- Номер (DOI, IBSN, Патент): 978-3-902613-16-5
- Изобретатель/автор: Feng Chen, Yong Yu, Yunjian Ge, Jian Sun, Xiaohong Deng
- Правопреемник/учебное заведение: Dept. of Automation, University Science and Technology of China, Dept. of Mechanical Engineering, Kagoshima University Japan, Institute of Intelligent Machines, Chinese Academy of Sciences China
- Дата публикации документа: 2007-10-31
- Страна опубликовавшая документ: Австрия
- Язык документа: Английский
- Наименование изделия: Не заполнено
- Источник: Climbing & Walking Robots, Towards New Applications, Book ed
- Вложения: Да
- Аналитик: Глаголева Елена
PAWL (power assist walking leg) represents a high integration of robotics, information technology, communication, control engineering, signal processing and etc. Today, trends in robotics research are changing from industrial applications to non-industrial applications, such as service robots, medical robots, humanoid robots, personal robots and so on. Human ability to perform physical tasks is limited not only by intelligence, but also by physical strength (Kazerooni, 1990). Our research on robot is using mechanism to augment human muscle and capability of sense during walking; synchronously, it can hold human agility and sense of direct operation. The primary task of this project is to develop a power assist walking support leg (shown in Fig.1) which not only amplifies strength of human legs and enhances endurance during walking, but also reduces user inner force.
Категория: Научные статьи | Нет комментариев »
A pilot clinical study on robotic assisted rehabilitation in VR with an arm exoskeleton device
- Тип контента: Научная статья
- Номер документа: 1128
- Название документа: A pilot clinical study on robotic assisted rehabilitation in VR with an arm exoskeleton device
- Номер (DOI, IBSN, Патент): 10.1109/ICVR.2007.4362131
- Изобретатель/автор: Rossi, B., Procopio, Caterina, Montagner, A., Frisoli, A., Carboncini, M.C., Borelli, L., Bergamasco, M.
- Правопреемник/учебное заведение: PERCRO Laboratory - Scuola Superiore Sant¿Anna, via Rinaldo Piaggio, 34, 56025 - Pontedera (Pisa), Italy
- Дата публикации документа: 2007-10-22
- Страна опубликовавшая документ: Италия
- Язык документа: Английский
- Наименование изделия: Не заполнено
- Источник: http://ieeexplore.ieee.org/search/freesrchabstract.jsp?tp=&a
- Вложения: Да
- Аналитик: Дмитрий Соловьев
The development of new robotic devices for rehabilitation can lead to new and more efficient therapeutic procedures. Moreover, the use of VR-based scenarios in which patients perform rehabilitation exercises dramatically increases the patients¿ motivation and thus the final therapy outcome. In this paper preliminary results of a pilot study carried out with an exoskeleton for the robotic assisted rehabilitation of the upper limb are presented. The paper briefly describes the main kinematic and mechanical features of the exoskeleton system, showing its peculiar characteristics which make it useful for rehabilitation purposes. The implementation of three different robotic schemes of therapy in virtual reality with this exoskeleton, based on an impedance control architecture, are presented and discussed in detail. Finally, qualitative and quantitative results obtained in a 6 week pilot study with three chronic stroke patients are reported.
Категория: Научные статьи | Нет комментариев »
EMG-Based Neuro-Fuzzy Control of a 4DOF Upper-Limb Power-Assist Exoskeleton
- Тип контента: Научная статья
- Номер документа: 563
- Название документа: EMG-Based Neuro-Fuzzy Control of a 4DOF Upper-Limb Power-Assist Exoskeleton
- Номер (DOI, IBSN, Патент): 10.1109/IEMBS.2007.4352969
- Изобретатель/автор: Liyanage, M., Kiguchi, K., Imada, Y.
- Правопреемник/учебное заведение: Saga Univ., Saga
- Дата публикации документа: 2007-10-22
- Страна опубликовавшая документ: Япония
- Язык документа: Английский
- Наименование изделия: Не заполнено
- Источник: http://ieeexplore.ieee.org/search/freesrchabstract.jsp?tp=&a
- Вложения: Да
- Аналитик: Дмитрий Соловьев
We have been developing a 4DOF exoskeleton robot system in order to assist shoulder vertical motion, shoulder horizontal motion, elbow motion, and forearm motion of physically weak persons such as elderly, injured, or disabled persons. The robot is directly attached to a user’s body and activated based on EMG (electromyogram) signals of the user’s muscles, since the EMG signals directly reflect the user’s motion intention. A neuro-fuzzy controller has been applied to control the exoskeleton robot system. In this paper, controller adaptation method to user’s EMG signals is proposed. A motion indicator is introduced to indicate the motion intention of the user for the controller adaptation. The experimental results show the effectiveness of the proposed method.
Категория: Научные статьи | Нет комментариев »
A planar 3DOF robotic exoskeleton for rehabilitation and assessment
- Тип контента: Научная статья
- Номер документа: 538
- Название документа: A planar 3DOF robotic exoskeleton for rehabilitation and assessment
- Номер (DOI, IBSN, Патент): 10.1109/IEMBS.2007.4353216
- Изобретатель/автор: Scott, S.H., Brown, I.E., Ball, S.J.
- Правопреемник/учебное заведение: Queen's Univ., Kingston
- Дата публикации документа: 2007-10-22
- Страна опубликовавшая документ: Канада
- Язык документа: Английский
- Наименование изделия: Не заполнено
- Источник: http://ieeexplore.ieee.org/search/freesrchabstract.jsp?tp=&a
- Вложения: Да
- Аналитик: Дмитрий Соловьев
A new robotic exoskeleton for the upper-limb has been designed and constructed. Its primary purpose is to act as a proof-of-concept prototype for a more sophisticated rehabilitation and assessment device that is currently in development. Simultaneously, it is intended to extend the capabilities of an existing planar exoskeleton device. The robot operates in the horizontal plane and provides independent control of a user’s shoulder, elbow and wrist joints using a cable-driven actuation system. The novel component of the design is a curved track and carriage which allows the mechanism that drives the shoulder joint to be located away from the user, underneath their arm. This paper describes the design of the robot, and provides an initial indication of its performance.
Категория: Научные статьи | Нет комментариев »
International Assessment of Research and Development in Brain-Computer Interfaces
- Тип контента: Научная статья
- Номер документа: 6697
- Название документа: International Assessment of Research and Development in Brain-Computer Interfaces
- Номер (DOI, IBSN, Патент): Не заполнено
- Изобретатель/автор: Theodore W. Berger (Chair), John K. Chapin, Greg A. Gerhardt, Dennis J. McFarland, José C. Principe, Walid V. Soussou, Dawn M. Taylor, Patrick A. Tresco
- Правопреемник/учебное заведение: World Technology Evaluation Center, Inc.
- Дата публикации документа: 2007-10-10
- Страна опубликовавшая документ: США
- Язык документа: Английский
- Наименование изделия: Не заполнено
- Источник: World Technology Evaluation Center, Inc. 4800 Roland Avenue
- Вложения: Да
- Аналитик: Глаголева Елена
Brain-computer interface (BCI) research deals with establishing commu-nication pathways between the brain and external devices. BCI systems can be broadly classified depending on the placement of the electrodes used to detect and measure neurons firing in the brain: in invasive systems, electrodes are inserted directly into the cortex; in noninvasive systems, they are placed on the scalp and use electroencephalography or electrocorticography to detect neuron activity. This WTEC study was designed to gather information on worldwide status and trends in BCI research and to disseminate it to government decisionmakers and the research community. The study reviewed and assessed the state of the art in sensor technology, the bioticabiotic interface and biocompatibility, data analysis and modeling, hard-ware implementation, systems engineering, functional electrical stimulation, noninvasive communication systems, and cognitive and emotional neuroprostheses in academic research and industry. The WTEC panel identified several major trends in current and evolving BCI research in North America, Europe, and Asia. First, BCI research throughout the world is extensive, with the magnitude of that research clearly on the rise. Second, BCI research is rapidly approaching a level of first-generation medical practice; moreover, BCI research is expected to rapidly accelerate in nonmedical arenas of commerce as well, particularly in the gaming, automotive, and robotics industries. Third, the focus of BCI research throughout the world is decidedly uneven, with invasive BCIs almost exclusively centered in North America, noninvasive BCI systems evolving primarily from European and Asian efforts, and the integration of BCIs and robotics systems championed by Asian research programs. In terms of funding, BCI and brain-controlled robotics programs have been a hallmark of recent European research and technological development. The range and investment levels of multidisciplinary, multinational, multilaboratory programs in Europe appear to far exceed that of most university and government-funded BCI programs in the United States and Canada. Although several U.S. government programs are advancing neural prostheses and BCIs, private sources have yet to make a major impact on BCI research in North America generally. However, the U.S. Small Business Innovative Re-search grants (SBIRs) and Small Technology Transfer Research grants (STTRs) have been effective in promoting transition from basic research to precommercialized prototypes. In Asia, China is investing hea-vily in biological sciences and engineering in general, and the extent of investment in BCI and BCI-related research has grown particularly rapidly; still, the panel observed little coordination between various programs. Japanese universities, research institutes, and laboratories also are increasing their investment in BCI research. Japan is especially vigorous in pursuing nonmedical applications and exploiting its expertise in BCI-controlled robotics. The WTEC panel concludes that there are abundant and fertile opportunities for worldwide collaborations in BCI research and allied fields.
Категория: Научные статьи | Нет комментариев »
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