Archive for Июнь 23rd, 2009

Kinematics analysis, workspace, design and control of 3-RPS and TRIGLIDE medical parallel robots

Дата: Июнь 23rd, 2009 Автор:
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  • Тип контента: Научная статья
  • Номер документа: 1480
  • Название документа: Kinematics analysis, workspace, design and control of 3-RPS and TRIGLIDE medical parallel robots
  • Номер (DOI, IBSN, Патент): 10.1109/HSI.2009.5090962
  • Изобретатель/автор: Verdes, D., Stan, S.-D., Maties, V., Manic, M., Balan, R.
  • Правопреемник/учебное заведение: Dept. of Mechatron., Tech. Univ. of Cluj-Napoca, Cluj-Napoca
  • Дата публикации документа: 2009-06-23
  • Страна опубликовавшая документ: Румыния
  • Язык документа: Английский
  • Наименование изделия: Не заполнено
  • Источник: http://ieeexplore.ieee.org/search/freesrchabstract.jsp?tp=&a
  • Вложения: Да
  • Аналитик: Дмитрий Соловьев

Parallel robots find many applications in human-systems interaction, medical robots, rehabilitation, exoskeletons, to name a few. These applications are characterized by many imperatives, with robust precision and dynamic workspace computation as the two ultimate ones. This paper presents kinematic analysis, workspace, design and control to 3 degrees of freedom (DOF) parallel robots. Parallel robots have received considerable attention from both researchers and manufacturers over the past years because of their potential for high stiffness, low inertia and high speed capability. Therefore, the 3 DOF translation parallel robots provide high potential and good prospects for their practical implementation in human-systems interaction.

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Kinematics, workspace, design and accuracy analysis of RPRPR medical parallel robot

Дата: Июнь 23rd, 2009 Автор:
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  • Тип контента: Научная статья
  • Номер документа: 1430
  • Название документа: Kinematics, workspace, design and accuracy analysis of RPRPR medical parallel robot
  • Номер (DOI, IBSN, Патент): 10.1109/HSI.2009.5090957
  • Изобретатель/автор: Szep, C., Stan, S.-D., Manic, M., Csibi, V., Balan, R.
  • Правопреемник/учебное заведение: Dept. of Mechatron., Tech. Univ. of Cluj-Napoca, Cluj-Napoca
  • Дата публикации документа: 2009-06-23
  • Страна опубликовавшая документ: Румыния
  • Язык документа: Английский
  • Наименование изделия: Не заполнено
  • Источник: http://ieeexplore.ieee.org/search/freesrchabstract.jsp?tp=&a
  • Вложения: Да
  • Аналитик: Дмитрий Соловьев

In recent years, parallel robots find many applications in human-systems interaction, medical robots, rehabilitation, exoskeletons, to name a few. These applications are characterized by many imperatives, with robust precision and dynamic workspace computation as the two ultimate ones. Practical methods of kinematic’s calibration make use of the linear differential error of the kinematics’ model. This model is based on the Jacobian of the direct kinematics’ model with respect to parameters of this model. The definition of the robot accuracy is usually related to robot positioning, so that the accuracy is defined as a measure of robot ability to attain a required position with respect to a fixed absolute reference coordinate frame. Such a definition is easily extended to trajectory tracking. Then, accuracy can be defined as a measure of robot ability to track the prescribed trajectory with respect to the absolute coordinate frame.

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A pneumatically powered knee-ankle-foot orthosis (KAFO) with myoelectric activation and inhibition

Дата: Июнь 23rd, 2009 Автор:
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  • Тип контента: Научная статья
  • Номер документа: 6344
  • Название документа: A pneumatically powered knee-ankle-foot orthosis (KAFO) with myoelectric activation and inhibition
  • Номер (DOI, IBSN, Патент): 10.1186/1743-0003-6-23
  • Изобретатель/автор: Gregory S Sawicki, Daniel P Ferris
  • Правопреемник/учебное заведение: University of Michigan
  • Дата публикации документа: 2009-06-23
  • Страна опубликовавшая документ: США
  • Язык документа: Английский
  • Наименование изделия: Не заполнено
  • Источник: Journal of NeuroEngineering and Rehabilitation
  • Вложения: Да
  • Аналитик: Глаголева Елена

Background: The goal of this study was to test the mechanical performance of a prototype kneeankle-foot orthosis (KAFO) powered by artificial pneumatic muscles during human walking. We had previously built a powered ankle-foot orthosis (AFO) and used it ef-fectively in studies on human motor adaptation, locomotion energetics, and gait rehabilitation. Extending the previous AFO to a KAFO presented additional challenges related to the force-length properties of the artificial pneumatic muscles and the presence of multiple antagonistic artificial pneumatic muscle pairs. Methods: Three healthy males were fitted with custom KAFOs equipped with artificial pneumatic muscles to power ankle plantar flexion/dorsiflexion and knee extension/flexion. Subjects walked over ground at 1.25 m/s under four conditions without extensive practice: 1) without wearing the orthosis, 2) wearing the orthosis with artificial muscles turned off, 3) wearing the orthosis activated under direct proportional myoelectric control, and 4) wearing the orthosis ac-tivated under proportional myoelectric control with flexor inhibition produced by leg extensor muscle activation. We collected joint kinematics, ground reaction forces, electromyography, and orthosis kinetics. Results: The KAFO produced ~22%–33% of the peak knee flexor moment, ~15%–33% of the peak extensor moment, ~42%–46% of the peak plantar flexor moment, and ~83%–129% of the peak dorsiflexor moment during normal walking. With flexor inhibition produced by leg extensor muscle activation, ankle (Pearson r-value = 0.74 ± 0.04) and knee ( r = 0.95 ± 0.04) joint kinematic profiles were more similar to the without orthosis condition compared to when there was no flexor inhibition (r = 0.49 ± 0.13 for ankle, p = 0.05, and r = 0.90 ± 0.03 for knee, p = 0.17). Conclusion: The proportional myoelectric control with flexor inhibition allowed for a more normal gait than direct proportional myoelectric con-trol. The current orthosis design provided knee torques smaller than the ankle torques due to the trade-off in torque and range of motion that occurs with artificial pneumatic muscles. Future KAFO designs could incorporate cams, gears, or different actuators to transmit greater torque to the knee.

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Development of a biomechanical energy harvester

Дата: Июнь 23rd, 2009 Автор:
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  • Тип контента: Научная статья
  • Номер документа: 6341
  • Название документа: Development of a biomechanical energy harvester
  • Номер (DOI, IBSN, Патент): 10.1186/1743-0003-6-22
  • Изобретатель/автор: Qingguo Li, Veronica Naing, J Maxwell Donelan
  • Правопреемник/учебное заведение: Queen's University, Kinston, Simon Fraser University, Burnaby
  • Дата публикации документа: 2009-06-23
  • Страна опубликовавшая документ: Канада
  • Язык документа: Английский
  • Наименование изделия: Не заполнено
  • Источник: Journal of NeuroEngineering and Rehabilitation
  • Вложения: Да
  • Аналитик: Глаголева Елена

Background: Biomechanical energy harvesting–generating electricity from people during daily activities–is a promising alternative to batteries for powering increasingly sophisticated portable devices. We recently developed a wearable knee-mounted energy harves-ting device that generated electricity during human walking. In this methods-focused paper, we explain the physiological principles that guided our design process and present a detailed description of our device design with an emphasis on new analyses. Methods: Effectively harvesting energy from walking requires a small lightweight device that efficiently converts intermittent, bi- irectio-nal, low speed and high torque mechanical power to electricity, and selectively engages power generation to assist muscles in per-forming negative mechanical work. To achieve this, our device used a one-way clutch to transmit only knee extension motions, a spur gear transmission to amplify the angular speed, a brushless DC rotary magnetic generator to convert the mechanical power into elec-trical power, a control system to determine when to open and close the power generation circuit based on measurements of knee angle, and a customized orthopaedic knee brace to distribute the device reaction torque over a large leg surface area. Results: The device selectively engaged power generation towards the end of swing extension, assisting knee flexor muscles by producing subs-tantial flexion torque (6.4 Nm), and efficiently converted the input mechanical power into electricity (54.6%). Consequently, six subjects walking at 1.5 m/s generated 4.8 ± 0.8 W of electrical power with only a 5.0 ± 21 W increase in metabolic cost. Conclusion: Biomechanical energy harvesting is capable of generating substantial amounts of electrical power from walking with lit-tle additional user effort making future versions of this technology particularly promising for charging portable medical devices.

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