�ݺ�ߣshows by User: abida16

�ݺ�ߣshows by User: abida16 / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: abida16 / Wed, 03 Sep 2014 00:45:13 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: abida16 Emg driven ipmc based artificial muscle finger /slideshow/emg-driven-ipmc-based-artificial-muscle-finger-38630376/38630376 emgdrivenipmc1-140903004513-phpapp02
The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. This can be stimulated by supplying a small voltage of 3V and shows evidence of a large bending behavior. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot. ]]>
The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. This can be stimulated by supplying a small voltage of 3V and shows evidence of a large bending behavior. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot. ]]> Wed, 03 Sep 2014 00:45:13 GMT /slideshow/emg-driven-ipmc-based-artificial-muscle-finger-38630376/38630376 abida16@slideshare.net(abida16) Emg driven ipmc based artificial muscle finger abida16 The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. This can be stimulated by supplying a small voltage of 3V and shows evidence of a large bending behavior. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/emgdrivenipmc1-140903004513-phpapp02-thumbnail.jpg?width=120&height=120&fit=bounds" /> The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. This can be stimulated by supplying a small voltage of 3V and shows evidence of a large bending behavior. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot.

Emg driven ipmc based artificial muscle finger from Abida Zama

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0 EMG Driven IPMC Based Artificial Muscle Finger /slideshow/emg-driven-ipmc-based-artificial-muscle-finger/38630165 artificialmusclefinger4003-140903003521-phpapp01
The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot.]]>
The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot.]]> Wed, 03 Sep 2014 00:35:21 GMT /slideshow/emg-driven-ipmc-based-artificial-muscle-finger/38630165 abida16@slideshare.net(abida16) EMG Driven IPMC Based Artificial Muscle Finger abida16 The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/artificialmusclefinger4003-140903003521-phpapp01-thumbnail.jpg?width=120&height=120&fit=bounds" /> The medical, rehabilitation and bio-mimetic technology demands human actuated devices which can support in the daily life activities such as functional assistance or functional substitution of human organs. These devices can be used in the form of prosthetic, skeletal and artificial muscles devices. However, we still have some difficulties in the practical use of these devices. The major challenges to overcome are the acquisition of the user’s intention from his or her bionic signals and to provide with an appropriate control signal for the device. Also, we need to consider the mechanical design issues such as lightweight and small size with flexible behavior etc. For the bionic signals, the electromyography (EMG) signal can be used to control these devices, which reflect the muscles motion, and can be acquired from the body surface. We are familiar with the fact that Ionic polymer metal composite (IPMC) has tremendous potential as an artificial muscle. In place of the supply voltage from external source for actuating an IPMC, EMG signal can be used where EMG electrodes show a reliable approach to extract voltage signal from body. Using this voltage signal via EMG sensor, IPMC can illustrate the bio-mimetic behavior through the movement of human muscles. Therefore, an IPMC is used as an artificial muscle finger for the bio-mimetic/micro robot.

EMG Driven IPMC Based Artificial Muscle Finger from Abida Zama

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0 Bio Robotics /slideshow/bio-robotics-30783201/30783201 biorobotics-140203232936-phpapp01
DISEASE DETECTOR- an Instrument for an Improved Quality of Life. An Application for the Analysis of MotorNeuron Diseases ]]>
DISEASE DETECTOR- an Instrument for an Improved Quality of Life. An Application for the Analysis of MotorNeuron Diseases ]]> Mon, 03 Feb 2014 23:29:36 GMT /slideshow/bio-robotics-30783201/30783201 abida16@slideshare.net(abida16) Bio Robotics abida16 DISEASE DETECTOR- an Instrument for an Improved Quality of Life. An Application for the Analysis of MotorNeuron Diseases <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/biorobotics-140203232936-phpapp01-thumbnail.jpg?width=120&height=120&fit=bounds" /> DISEASE DETECTOR- an Instrument for an Improved Quality of Life. An Application for the Analysis of MotorNeuron Diseases

Bio Robotics from Abida Zama

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0 Biorobotics Abstract /slideshow/biorobotics-abstract/30782592 bioroboticsfinal-140203230255-phpapp02
Biorobotics: an Instrument for an Improved Quality of Life. An Application for the Analysis of Neuromotor Diseases ]]>
Biorobotics: an Instrument for an Improved Quality of Life. An Application for the Analysis of Neuromotor Diseases ]]> Mon, 03 Feb 2014 23:02:55 GMT /slideshow/biorobotics-abstract/30782592 abida16@slideshare.net(abida16) Biorobotics Abstract abida16 Biorobotics: an Instrument for an Improved Quality of Life. An Application for the Analysis of Neuromotor Diseases <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/bioroboticsfinal-140203230255-phpapp02-thumbnail.jpg?width=120&height=120&fit=bounds" /> Biorobotics: an Instrument for an Improved Quality of Life. An Application for the Analysis of Neuromotor Diseases

Biorobotics Abstract from Abida Zama

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0 EMI/EMC /slideshow/emiemc-28086601/28086601 myemc1ppt-copy-131110075854-phpapp02
BASICS OF CROSSTALK, TRANSIENTS IN POWER SUPPLY LINES, OATS]]>
BASICS OF CROSSTALK, TRANSIENTS IN POWER SUPPLY LINES, OATS]]> Sun, 10 Nov 2013 07:58:54 GMT /slideshow/emiemc-28086601/28086601 abida16@slideshare.net(abida16) EMI/EMC abida16 BASICS OF CROSSTALK, TRANSIENTS IN POWER SUPPLY LINES, OATS <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/myemc1ppt-copy-131110075854-phpapp02-thumbnail.jpg?width=120&height=120&fit=bounds" /> BASICS OF CROSSTALK, TRANSIENTS IN POWER SUPPLY LINES, OATS

EMI/EMC from Abida Zama

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0 Wi gig abstract /abida16/wi-gig-abstract wigigabstract-130307025147-phpapp02
Wireless Gigabit Alliance]]>
Wireless Gigabit Alliance]]> Thu, 07 Mar 2013 02:51:47 GMT /abida16/wi-gig-abstract abida16@slideshare.net(abida16) Wi gig abstract abida16 Wireless Gigabit Alliance <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/wigigabstract-130307025147-phpapp02-thumbnail.jpg?width=120&height=120&fit=bounds" /> Wireless Gigabit Alliance

Wi gig abstract from Abida Zama

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0 Wi-Gig (Wireless Gigabit Alliance) ppt /slideshow/wi-gig-ppt/16998043 wi-gigppt-130307024203-phpapp02
Frustrated by unsecured Wi-Fi, a fix is on the way….]]>
Frustrated by unsecured Wi-Fi, a fix is on the way….]]> Thu, 07 Mar 2013 02:42:03 GMT /slideshow/wi-gig-ppt/16998043 abida16@slideshare.net(abida16) Wi-Gig (Wireless Gigabit Alliance) ppt abida16 Frustrated by unsecured Wi-Fi, a fix is on the way…. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/wi-gigppt-130307024203-phpapp02-thumbnail.jpg?width=120&height=120&fit=bounds" /> Frustrated by unsecured Wi-Fi, a fix is on the way….

Wi-Gig (Wireless Gigabit Alliance) ppt from Abida Zama

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0 https://cdn.slidesharecdn.com/profile-photo-abida16-48x48.jpg?cb=1523230016 Tell me and I forget, teach me and I may remember, involve me and I learn. https://cdn.slidesharecdn.com/ss_thumbnails/emgdrivenipmc1-140903004513-phpapp02-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/emg-driven-ipmc-based-artificial-muscle-finger-38630376/38630376 Emg driven ipmc based ... https://cdn.slidesharecdn.com/ss_thumbnails/artificialmusclefinger4003-140903003521-phpapp01-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/emg-driven-ipmc-based-artificial-muscle-finger/38630165 EMG Driven IPMC Based ... https://cdn.slidesharecdn.com/ss_thumbnails/biorobotics-140203232936-phpapp01-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/bio-robotics-30783201/30783201 Bio Robotics