Wearable Robots, Industrial Exoskeletons: Market Shares, Market Strategies, and Market Forecasts, 2016 to 2021
Wearable robots, industrial exoskeletons are used for permitting workers to lift 250 pounds and not get hurt while lifting, this is as close to superhuman powers as the comic books have imagined. The industrial exoskeletons are used to assist with weight lifting for workers while being as easy to use as getting dressed in the morning: Designs with multiple useful features are available. The study has 454 pages and 164 tables and figures.
Industrial workers and warfighters can perform at a higher level when wearing an exoskeleton. Exoskeletons can enable aerospace workers to work more efficiently when building or repairing airplanes. Industrial robots are very effective for ship building where heavy lifting can injure workers.
Exoskeleton devices have the potential to be adapted further for expanded use in every aspect of industry. Workers benefit from powered human augmentation technology because they can offload some of the dangerous part of lifting and supporting heavy tools. Robots assist wearers with lifting activities, improving the way that a job is performed and decreasing the quantity of disability. For this reason it is anticipated that industrial exoskeleton robots will have very rapid adoption once they are fully tested and proven to work effectively for a particular task.
Exoskeletons are being developed in the U.S., China, Korea, Japan, and Europe. They are generally intended for logistical and engineering purposes, due to their short range and short battery life. Most exoskeletons can operate independently for several hours. Chinese manufacturers express hope that upgrades to exoskeletons extending the battery life could make them suitable for frontline infantry in difficult environments, including mountainous terrain.
Exoskeletons are capable of transferring the weight of heavy loads to the ground through powered legs without loss of human mobility. This can increase the distance that soldiers can cover in a day, or increase the load that they can carry though difficult terrain. Exoskeletons can significantly reduce operator fatigue and exposure to injury. Industrial robots help with lifting, walking, and sitting Exoskeletons can be used to access efficiency of movement and improve efficiency.
Industrial workers and warfighters can perform at a higher level when wearing an exoskeleton. Exoskeletons can enable aerospace workers to work more efficiently when building or repairing airplanes. Industrial robots are very effective for ship building where heavy lifting can injure workers. Medical and military uses have driven initial exoskeleton development to date. New market opportunities of building and repair in the infrastructure, aerospace, and shipping industries offer large opportunity for growth of the exoskeleton markets.
Wearable robots, exoskeletons units are evolving additional functionality rapidly. Wearable robots functionality is used to assist to personal mobility via exoskeleton robots. They promote upright walking and relearning of lost functions. Exoskeletons are helping older people move after a stroke. Exoskeleton s deliver higher quality rehabilitation, provide the base for a growth strategy for clinical facilities.
Exoskeletons support occupational heavy lifting. Exoskeletons are poised to play a significant role in warehouse management, ship building, and manufacturing. Usefulness in occupational markets is being established. Emerging markets promise to have dramatic and rapid growth.
Industrial workers and warfighters can perform at a higher level when wearing an exoskeleton. Exoskeletons can enable paraplegics to walk again. Devices have the potential to be adapted further for expanded use in healthcare and industry. Elderly people benefit from powered human augmentation technology. Robots assist wearers with walking and lifting activities, improving the health and quality of life for aging populations.
Exoskeletons are being developed in the U.S., China, Korea, Japan, and Europe. They are useful in medical markets. They are generally intended for logistical and engineering purposes, due to their short range and short battery life. Most exoskeletons can operate independently for several hours. Chinese manufacturers express hope that upgrades to exoskeletons extending the battery life could make them suitable for frontline infantry in difficult environments, including mountainous terrain.
In the able-bodied field, Ekso, Lockheed Martin, Sarcos / Raytheon, BAE Systems, Panasonic, Honda, Daewoo, Noonee, Revision Military, and Cyberdyne are each developing some form of exoskeleton for military and industrial applications. The field of robotic exoskeleton technology remains in its infancy.
Robotics has tremendous ability to support work tasks and reduce disability. Disability treatment with sophisticated exoskeletons is anticipated to providing better outcomes for patients with paralysis due to traumatic injury. With the use of exoskeletons, patient recovery of function is subtle or non existent, but getting patients able to walk and move around is of substantial benefit. People using exoskeleton robots are able to make continued progress in regaining functionality even years after an injury.
Wearable Robots, Exoskeletons at $36.5 million in 2015 are anticipated to reach $2.1 billion by 2021. All the measurable revenue in 2015 is from medical exoskeletons. New technology from a range of vendors provides multiple designs that actually work and will be on the market soon. This bodes well for market development.
WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, electronics.ca, and Thompson Financial. WinterGreen Research is positioned to help customers facing challenges that define the modern enterprises. The increasingly global nature of science, technology and engineering is a reflection of the implementation of the globally integrated enterprise. Customers trust wintergreen research to work alongside them to ensure the success of the participation in a particular market segment.
WinterGreen Research supports various market segment programs; provides trusted technical services to the marketing departments. It carries out accurate market share and forecast analysis services for a range of commercial and government customers globally. These are all vital market research support solutions requiring trust and integrity.
Industrial workers and warfighters can perform at a higher level when wearing an exoskeleton. Exoskeletons can enable aerospace workers to work more efficiently when building or repairing airplanes. Industrial robots are very effective for ship building where heavy lifting can injure workers.
Exoskeleton devices have the potential to be adapted further for expanded use in every aspect of industry. Workers benefit from powered human augmentation technology because they can offload some of the dangerous part of lifting and supporting heavy tools. Robots assist wearers with lifting activities, improving the way that a job is performed and decreasing the quantity of disability. For this reason it is anticipated that industrial exoskeleton robots will have very rapid adoption once they are fully tested and proven to work effectively for a particular task.
Exoskeletons are being developed in the U.S., China, Korea, Japan, and Europe. They are generally intended for logistical and engineering purposes, due to their short range and short battery life. Most exoskeletons can operate independently for several hours. Chinese manufacturers express hope that upgrades to exoskeletons extending the battery life could make them suitable for frontline infantry in difficult environments, including mountainous terrain.
Exoskeletons are capable of transferring the weight of heavy loads to the ground through powered legs without loss of human mobility. This can increase the distance that soldiers can cover in a day, or increase the load that they can carry though difficult terrain. Exoskeletons can significantly reduce operator fatigue and exposure to injury. Industrial robots help with lifting, walking, and sitting Exoskeletons can be used to access efficiency of movement and improve efficiency.
Industrial workers and warfighters can perform at a higher level when wearing an exoskeleton. Exoskeletons can enable aerospace workers to work more efficiently when building or repairing airplanes. Industrial robots are very effective for ship building where heavy lifting can injure workers. Medical and military uses have driven initial exoskeleton development to date. New market opportunities of building and repair in the infrastructure, aerospace, and shipping industries offer large opportunity for growth of the exoskeleton markets.
Wearable robots, exoskeletons units are evolving additional functionality rapidly. Wearable robots functionality is used to assist to personal mobility via exoskeleton robots. They promote upright walking and relearning of lost functions. Exoskeletons are helping older people move after a stroke. Exoskeleton s deliver higher quality rehabilitation, provide the base for a growth strategy for clinical facilities.
Exoskeletons support occupational heavy lifting. Exoskeletons are poised to play a significant role in warehouse management, ship building, and manufacturing. Usefulness in occupational markets is being established. Emerging markets promise to have dramatic and rapid growth.
Industrial workers and warfighters can perform at a higher level when wearing an exoskeleton. Exoskeletons can enable paraplegics to walk again. Devices have the potential to be adapted further for expanded use in healthcare and industry. Elderly people benefit from powered human augmentation technology. Robots assist wearers with walking and lifting activities, improving the health and quality of life for aging populations.
Exoskeletons are being developed in the U.S., China, Korea, Japan, and Europe. They are useful in medical markets. They are generally intended for logistical and engineering purposes, due to their short range and short battery life. Most exoskeletons can operate independently for several hours. Chinese manufacturers express hope that upgrades to exoskeletons extending the battery life could make them suitable for frontline infantry in difficult environments, including mountainous terrain.
In the able-bodied field, Ekso, Lockheed Martin, Sarcos / Raytheon, BAE Systems, Panasonic, Honda, Daewoo, Noonee, Revision Military, and Cyberdyne are each developing some form of exoskeleton for military and industrial applications. The field of robotic exoskeleton technology remains in its infancy.
Robotics has tremendous ability to support work tasks and reduce disability. Disability treatment with sophisticated exoskeletons is anticipated to providing better outcomes for patients with paralysis due to traumatic injury. With the use of exoskeletons, patient recovery of function is subtle or non existent, but getting patients able to walk and move around is of substantial benefit. People using exoskeleton robots are able to make continued progress in regaining functionality even years after an injury.
Wearable Robots, Exoskeletons at $36.5 million in 2015 are anticipated to reach $2.1 billion by 2021. All the measurable revenue in 2015 is from medical exoskeletons. New technology from a range of vendors provides multiple designs that actually work and will be on the market soon. This bodes well for market development.
WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, electronics.ca, and Thompson Financial. WinterGreen Research is positioned to help customers facing challenges that define the modern enterprises. The increasingly global nature of science, technology and engineering is a reflection of the implementation of the globally integrated enterprise. Customers trust wintergreen research to work alongside them to ensure the success of the participation in a particular market segment.
WinterGreen Research supports various market segment programs; provides trusted technical services to the marketing departments. It carries out accurate market share and forecast analysis services for a range of commercial and government customers globally. These are all vital market research support solutions requiring trust and integrity.
WEARABLE ROBOTS, INDUSTRIAL EXOSKELETONS: MARKET SHARES, MARKET STRATEGY, AND MARKET FORECASTS, 2016 TO 20211
WEARABLE ROBOT EXOSKELETON EXECUTIVE SUMMARY
Wearable Robot Exoskeleton Market Driving Forces
Exoskeleton Market Driving Forces
Industrial Exoskeleton Devices Positioned to Serve Commercial Wearable Purposes
Transition from Military Markets to Commercial Exoskeleton Markets
Wearable Exoskeleton Market Shares
Wearable Robot, Exoskeleton Market Forecasts
1. WEARABLE ROBOT EXOSKELETON MARKET DESCRIPTION AND MARKET DYNAMICS
1.1 Wearable Robot Exoskeleton Market Definition
1.2 Market Growth Drivers For Exoskeletons
1.3 Industrial Active And Passive Wearable Exoskeletons
1.4 Human Augmentation
1.4.1 Exoskeleton Technology
1.5 Safety Standards For Exoskeletons In Industry
2. EXOSKELETON MARKET SHARES AND MARKET FORECASTS
2.1 Exoskeleton Market Driving Forces
2.1.1 Industrial Exoskeleton Devices Positioned to Serve Commercial Wearable Purposes
2.1.2 Military Exoskeleton Markets Shift
2.2 Wearable Exoskeleton Market Shares
2.2.1 Able-Bodied Exoskeletons
2.2.2 UK Armed Police Super-Light Graphene Vests From US Army
2.2.3 Honda Builds Unique Transportation Exoskeleton Device Market
2.3 Wearable Commercial and Military Exoskeleton Market Forecasts
2.3.1 Wearable Commercial Exoskeleton Market Forecasts
2.4 Commercial Exoskeleton Market Segments
2.4.1 US Infrastructure: Bridges
2.4.2 Aerospace
2.4.3 Law Enforcement
2.4.4 Exoskeletons Change The Face Of Shipbuilding
2.4.5 Industrial Wearable Robot Shipyard Exoskeleton
2.4.6 Industrial Wearable Robots, Exoskeleton Robot Market Segments
2.4.7 Save Lives And Prevent Injury
2.5 Robot Industrial Markets
2.6 Medical Wearable Robot Exoskeleton, Paraplegic, Multiple Sclerosis, Stroke, And Cerebral Palsy Market Segments
2.6.1 Ekso Bionics Robotic Suit Helps Paralyzed Man Walk Again
2.6.2 Medical Market for Wearable Robotic Exoskeleton Devices
2.7 Exoskeleton Robots Regional Analysis
2.7.1 US
2.7.2 Europe
2.7.3 Japan
2.7.4 Korea
3. WEARABLE ROBOT EXOSKELETON PRODUCTS
3.1 Ekso
3.1.1 Ekso Exoskeletons and Body Armor for U.S. Special Operations Command (SOCOM)
3.1.2 Ekso TALOS Suit
3.1.3 Ekso SOCOM Collaborative Design Of The Project
3.1.4 Ekso Quiet Power Sources
3.1.5 Esko Technology
3.1.6 Ekso Bionics
3.1.7 Esko Exoskeletons
3.1.8 Ekso Builds Muscle Memory
3.1.9 Ekso Bionics Wearable Bionic Suit
3.1.10 Ekso Gait Training Exoskeleton Uses
3.1.11 Ekso Bionics Rehabilitation
3.1.12 Ekso Bionics Robotic Suit Helps Paralyzed Man Walk Again
3.2 Rewalk
3.2.1 Rewalk-Robotics-Personal Support
3.3 Lockheed Martin Exoskeleton Design
3.3.1 Lockheed Martin HULC® with Lift Assist Device Exoskeletons
3.3.2 Lockheed Martin Military Exoskeleton Human Universal Load Carrier (HULC) with Lift Assist Device
3.3.3 Lockheed Martin Fortis
3.3.4 Collaboration Between National Center for Manufacturing Sciences, Lockheed Martin, and BAE Systems
3.3.5 Lockheed Martin FORTIS Exoskeleton
3.4 Berkeley Robotics Laboratory Exoskeletons
3.4.1 Berkeley Robotics Austin
3.4.2 Berkley Robotics and Human Engineering Laboratory ExoHiker
3.4.3 Berkley Robotics and Human Engineering Laboratory ExoClimber
3.4.4 Berkeley Lower Extremity Exoskeleton (BLEEX)
3.4.5 Berkley Robotics and Human Engineering Laboratory Exoskeleton
3.4.6 Berkley Robotics and Human Engineering Laboratory
3.5 Bionic
3.6 Reha-Stim Harness
3.6.1 Reha-Stim Bi-Manu-Track Hand and Wrist
3.7 Exoskeleton Designed by CAR
3.8 Sarcos
3.8.1 Sarcos Guardian XO
3.8.2 Sarcos Robot-as-a-Service (RaaS) Model
3.8.3 Sarcos Raytheon XOS 2: Second Generation Exoskeleton
3.9 Cyberdyne
3.9.1 Cyberdyne HAL
3.9.2 Applications of Cyberdyne HAL
3.10 Berkley Robotics Laboratory Exoskeletons
3.10.1 Berkley Robotics and Human Engineering Laboratory ExoHiker
3.10.2 Berkley Robotics and Human Engineering Laboratory ExoClimber
3.10.3 Berkeley Lower Extremity Exoskeleton (BLEEX)
3.10.4 Berkley Robotics and Human Engineering Laboratory Exoskeleton
3.11 Rex Bionics
3.12 US Bionics
3.13 Noonee
3.13.1 Noonee Exoskeletons Chairless Chair
3.14 Hocoma
3.15 AlterG: PK100 PowerKnee
3.15.1 AlterG Bionic Leg
3.15.2 Alterg / Tibion Bionic Leg
3.15.3 AlterG M300
3.16 Catholic University of America Arm Therapy Robot ARMin III
3.17 U.S. Special Operations Command SOCOM Wearable Exoskeleton
3.17.1 DARPA Funded Exoskeleton
3.17.2 Darpa Secure, Smartphone Device
3.17.3 Trek Aerospace Springtail/XFV Exo-skeletor Flying Vehicle
3.18 Revision Military Kinetic Operations Suit
3.19 HEXORR: Hand EXOskeleton Rehabilitation Robot
3.20 Honda
3.20.1 Honda Walk Assist
3.20.2 Honda Prototype Stride Management Motorized Assist Device
3.20.3 Honda Builds Unique Transportation Exoskeleton Device Market
3.21 Revision Military - Exoskeleton Integrated Soldier Protection System
3.21.1 Revision Military Armored Exoskeleton
3.22 Mira Lopes Gait Rehabilitation Device
3.22.1 Prototype of University of Twente LOPES with 8 Actuated Degrees of Freedom
3.23 China North Industries Group Corporation (NORINCO)
3.23.1 Chinese Exoskeletons for Combat
3.24 Russian Army: Combat Exoskeletons By 2020
3.25 UK Exoskeleton
3.25.1 UK Exoskeleton Law Enforcement
3.25.2 UK Armed Police Super-Light Graphene Vests
3.25.3 Brain-Machine Interface (BMI) Based Robotic Exoskeleton
3.26 University of Texas in Austin: Robotic Upper-Body Rehab Exoskeleton215
3.27 Daewoo Begins Testing Robotic Exoskeletons for Shipyard Workers in South Korea
3.27.1 Daewoo Robotic Suit Gives Shipyard Workers Super Strength
3.27.2 Daewoo Shipbuilding & Marine Engineering
3.27.3 Daewoo Shipbuilding & Marine Engineering (DSME) Wearable Robot Tank Insulation Boxes of LNG Carriers
3.27.4 Daewoo
3.28 Panasonic
3.28.1 Panasonic Activelink
4. EXOSKELETON TECHNOLOGY
4.1 Industrial Robot Exoskeleton Standards
4.2 NCMS
4.3 Exoskeleton Standards Use Environment
4.3.1 Sarcos Guardian XOS Industrial Applications
4.3.2 UK Armed Police Super-Light Graphene Vests From US Army
4.3.3 Daewoo Wearable Robot Is Made Of Carbon, Aluminum Alloy And Steel
4.3.4 Cyberdyne HAL for Labor Support and HAL for Care Support Meet ISO
13482 STANDARD
4.4 Exoskeleton Technology
4.5 Robotic Actuator Energy
4.5.1 Elastic Actuators
4.5.2 General Atomics Hybrid-Electric Power Unit
4.6 Robotic Risk Mitigation
4.7 Exoskeleton Multi-Factor Solutions
4.7.1 Biometallic Materials Titanium (Ti) and its Alloys
4.8 Cognitive Science
4.9 Artificial Muscle
4.10 Standards
4.11 Regulations
5. EXOSKELETON COMPANY PROFILES
5.1 AlterG
5.1.1 AlterG: PK100 PowerKnee
5.1.2 AlterG Bionic Leg
5.1.3 AlterG M300 Customers
5.1.4 AlterG M300
5.1.5 AlterG™ Acquires Tibion Bionic Leg
5.2 Bionik Laboratories / Interactive Motion Technologies (IMT)
5.2.1 Bionik Laboratories Acquires Interactive Motion Technologies, Inc. (IMT)
5.2.2 BioNik / InMotion Robots for NHS study in the UK
5.2.3 Bionik / Interactive Motion Technologies (IMT) InMotion Robots
5.2.4 IMT Anklebot Evidence-Based Neurorehabilitation Technology
5.3 Catholic University of America Arm Therapy Robot ARMin III
5.3.1 Catholic University of America Armin Iii Project Description:
5.3.2 Catholic University of America HandSOME Hand Spring Operated Movement Enhancer
5.4 China North Industries Group Corporation (NORINCO)
5.4.1 China North Industries Corporation (NORINCO) Revenue
5.5 Cyberdyne
5.5.1 Cyberdyne Wants to Offer Robot Suit HAL in the U.S.
5.5.2 Robot Exoskeletons At Japan's Airports
5.5.3 To Offset Aging Workforce, Japan Turns to Robot-Worked Airports
5.6 Ekso Bionics
5.6.1 Esko Employees
5.6.2 Ekso Rehabilitation Robotics
5.6.3 Ekso GT
5.6.4 Ekso Fourth Quarter And Full Year 2015 Financial Results
5.6.5 Ekso Bionics Seeks To Lead The Technological Revolutions
5.6.6 Ekso Bionics Regional Presence
5.6.7 Ekso Bionics Customers
5.6.8 Ekso Able-Bodied Industrial Applications
5.6.9 Ekso Rehabilitation Robotics
5.7 Fanuc
5.7.1 Fanuc Revenue
5.7.2 Fanuc - Industrial Robot Automation Systems and Robodrill Machine Centers
5.8 Focal Meditech
5.8.1 Focal Meditech BV Collaborating Partners:
5.9 HEXORR: Hand EXOskeleton Rehabilitation Robot
5.10 Honda Motor
5.10.1 Honda Motor Revenue
5.10.2 Honda Automobile Business
5.10.3 Honda Walk Assist
5.10.4 Honda Prototype Stride Management Motorized Assist Device
5.10.5 Honda Builds Unique Transportation Exoskeleton Device Market
5.11 Interaxon
5.12 KDM
5.13 Lockheed Martin
5.13.1 Lockheed Martin First Quarter 2016 and 2015 Revenue
5.14 Lopes Gait Rehabilitation Device
5.15 MRISAR
5.16 Myomo
5.16.1 Myomo mPower 1000
5.17 Noonee
5.18 Orthocare Innovations
5.18.1 Orthocare Innovations Adaptive Systems™ For Advanced O&P Solutions.
5.18.2 Orthocare Innovations Company Highlights
5.19 Parker Hannifin
5.19.1 Parker Revenue for Fiscal 2016 and 2015 thrid Quarter Sales
5.19.2 Parker Hannifin Segment Results Fiscal 2015 Second Quarter
5.19.3 Parker and Freedom Innovations' Partnership
5.19.4 Parker Hannifin Indego License
5.20 Reha Technology
5.21 Revision Military
5.22 ReWalk Robotics
5.22.1 ReWalk Revenue
5.22.2 ReWalk First Mover Advantage
5.22.3 ReWalk Strategic Alliance with Yaskawa Electric Corporation
5.22.4 ReWalk Scalable Manufacturing Capability
5.22.5 ReWalk Leverages Core Technology Platforms
5.23 RexBionics
5.24 Robotdalen
5.25 Rostec
5.25.1 Rostec Lines Of Business
5.25.2 Rostec Corporation Objectives
5.26 RU Robots
5.27 Sarcos
5.27.1 Sarcos LC Acquires Raytheon Sarcos Unit
5.27.2 Sarcos LC Acquires Raytheon Sarcos Unit of Raytheon
5.28 Shepherd Center
5.29 Socom (U.S. Special Operations Command)
5.30 Trek Aerospace
5.31 University of Twente
5.32 United Instrument Manufacturing Corporation
5.33 Other Human Muscle Robotic Companies
5.33.1 Additional Rehabilitation Robots
5.33.2 Selected Rehabilitation Equipment Companies
5.33.3 Spinal Cord Treatment Centers in the US
WEARABLE ROBOT EXOSKELETON EXECUTIVE SUMMARY
Wearable Robot Exoskeleton Market Driving Forces
Exoskeleton Market Driving Forces
Industrial Exoskeleton Devices Positioned to Serve Commercial Wearable Purposes
Transition from Military Markets to Commercial Exoskeleton Markets
Wearable Exoskeleton Market Shares
Wearable Robot, Exoskeleton Market Forecasts
1. WEARABLE ROBOT EXOSKELETON MARKET DESCRIPTION AND MARKET DYNAMICS
1.1 Wearable Robot Exoskeleton Market Definition
1.2 Market Growth Drivers For Exoskeletons
1.3 Industrial Active And Passive Wearable Exoskeletons
1.4 Human Augmentation
1.4.1 Exoskeleton Technology
1.5 Safety Standards For Exoskeletons In Industry
2. EXOSKELETON MARKET SHARES AND MARKET FORECASTS
2.1 Exoskeleton Market Driving Forces
2.1.1 Industrial Exoskeleton Devices Positioned to Serve Commercial Wearable Purposes
2.1.2 Military Exoskeleton Markets Shift
2.2 Wearable Exoskeleton Market Shares
2.2.1 Able-Bodied Exoskeletons
2.2.2 UK Armed Police Super-Light Graphene Vests From US Army
2.2.3 Honda Builds Unique Transportation Exoskeleton Device Market
2.3 Wearable Commercial and Military Exoskeleton Market Forecasts
2.3.1 Wearable Commercial Exoskeleton Market Forecasts
2.4 Commercial Exoskeleton Market Segments
2.4.1 US Infrastructure: Bridges
2.4.2 Aerospace
2.4.3 Law Enforcement
2.4.4 Exoskeletons Change The Face Of Shipbuilding
2.4.5 Industrial Wearable Robot Shipyard Exoskeleton
2.4.6 Industrial Wearable Robots, Exoskeleton Robot Market Segments
2.4.7 Save Lives And Prevent Injury
2.5 Robot Industrial Markets
2.6 Medical Wearable Robot Exoskeleton, Paraplegic, Multiple Sclerosis, Stroke, And Cerebral Palsy Market Segments
2.6.1 Ekso Bionics Robotic Suit Helps Paralyzed Man Walk Again
2.6.2 Medical Market for Wearable Robotic Exoskeleton Devices
2.7 Exoskeleton Robots Regional Analysis
2.7.1 US
2.7.2 Europe
2.7.3 Japan
2.7.4 Korea
3. WEARABLE ROBOT EXOSKELETON PRODUCTS
3.1 Ekso
3.1.1 Ekso Exoskeletons and Body Armor for U.S. Special Operations Command (SOCOM)
3.1.2 Ekso TALOS Suit
3.1.3 Ekso SOCOM Collaborative Design Of The Project
3.1.4 Ekso Quiet Power Sources
3.1.5 Esko Technology
3.1.6 Ekso Bionics
3.1.7 Esko Exoskeletons
3.1.8 Ekso Builds Muscle Memory
3.1.9 Ekso Bionics Wearable Bionic Suit
3.1.10 Ekso Gait Training Exoskeleton Uses
3.1.11 Ekso Bionics Rehabilitation
3.1.12 Ekso Bionics Robotic Suit Helps Paralyzed Man Walk Again
3.2 Rewalk
3.2.1 Rewalk-Robotics-Personal Support
3.3 Lockheed Martin Exoskeleton Design
3.3.1 Lockheed Martin HULC® with Lift Assist Device Exoskeletons
3.3.2 Lockheed Martin Military Exoskeleton Human Universal Load Carrier (HULC) with Lift Assist Device
3.3.3 Lockheed Martin Fortis
3.3.4 Collaboration Between National Center for Manufacturing Sciences, Lockheed Martin, and BAE Systems
3.3.5 Lockheed Martin FORTIS Exoskeleton
3.4 Berkeley Robotics Laboratory Exoskeletons
3.4.1 Berkeley Robotics Austin
3.4.2 Berkley Robotics and Human Engineering Laboratory ExoHiker
3.4.3 Berkley Robotics and Human Engineering Laboratory ExoClimber
3.4.4 Berkeley Lower Extremity Exoskeleton (BLEEX)
3.4.5 Berkley Robotics and Human Engineering Laboratory Exoskeleton
3.4.6 Berkley Robotics and Human Engineering Laboratory
3.5 Bionic
3.6 Reha-Stim Harness
3.6.1 Reha-Stim Bi-Manu-Track Hand and Wrist
3.7 Exoskeleton Designed by CAR
3.8 Sarcos
3.8.1 Sarcos Guardian XO
3.8.2 Sarcos Robot-as-a-Service (RaaS) Model
3.8.3 Sarcos Raytheon XOS 2: Second Generation Exoskeleton
3.9 Cyberdyne
3.9.1 Cyberdyne HAL
3.9.2 Applications of Cyberdyne HAL
3.10 Berkley Robotics Laboratory Exoskeletons
3.10.1 Berkley Robotics and Human Engineering Laboratory ExoHiker
3.10.2 Berkley Robotics and Human Engineering Laboratory ExoClimber
3.10.3 Berkeley Lower Extremity Exoskeleton (BLEEX)
3.10.4 Berkley Robotics and Human Engineering Laboratory Exoskeleton
3.11 Rex Bionics
3.12 US Bionics
3.13 Noonee
3.13.1 Noonee Exoskeletons Chairless Chair
3.14 Hocoma
3.15 AlterG: PK100 PowerKnee
3.15.1 AlterG Bionic Leg
3.15.2 Alterg / Tibion Bionic Leg
3.15.3 AlterG M300
3.16 Catholic University of America Arm Therapy Robot ARMin III
3.17 U.S. Special Operations Command SOCOM Wearable Exoskeleton
3.17.1 DARPA Funded Exoskeleton
3.17.2 Darpa Secure, Smartphone Device
3.17.3 Trek Aerospace Springtail/XFV Exo-skeletor Flying Vehicle
3.18 Revision Military Kinetic Operations Suit
3.19 HEXORR: Hand EXOskeleton Rehabilitation Robot
3.20 Honda
3.20.1 Honda Walk Assist
3.20.2 Honda Prototype Stride Management Motorized Assist Device
3.20.3 Honda Builds Unique Transportation Exoskeleton Device Market
3.21 Revision Military - Exoskeleton Integrated Soldier Protection System
3.21.1 Revision Military Armored Exoskeleton
3.22 Mira Lopes Gait Rehabilitation Device
3.22.1 Prototype of University of Twente LOPES with 8 Actuated Degrees of Freedom
3.23 China North Industries Group Corporation (NORINCO)
3.23.1 Chinese Exoskeletons for Combat
3.24 Russian Army: Combat Exoskeletons By 2020
3.25 UK Exoskeleton
3.25.1 UK Exoskeleton Law Enforcement
3.25.2 UK Armed Police Super-Light Graphene Vests
3.25.3 Brain-Machine Interface (BMI) Based Robotic Exoskeleton
3.26 University of Texas in Austin: Robotic Upper-Body Rehab Exoskeleton215
3.27 Daewoo Begins Testing Robotic Exoskeletons for Shipyard Workers in South Korea
3.27.1 Daewoo Robotic Suit Gives Shipyard Workers Super Strength
3.27.2 Daewoo Shipbuilding & Marine Engineering
3.27.3 Daewoo Shipbuilding & Marine Engineering (DSME) Wearable Robot Tank Insulation Boxes of LNG Carriers
3.27.4 Daewoo
3.28 Panasonic
3.28.1 Panasonic Activelink
4. EXOSKELETON TECHNOLOGY
4.1 Industrial Robot Exoskeleton Standards
4.2 NCMS
4.3 Exoskeleton Standards Use Environment
4.3.1 Sarcos Guardian XOS Industrial Applications
4.3.2 UK Armed Police Super-Light Graphene Vests From US Army
4.3.3 Daewoo Wearable Robot Is Made Of Carbon, Aluminum Alloy And Steel
4.3.4 Cyberdyne HAL for Labor Support and HAL for Care Support Meet ISO
13482 STANDARD
4.4 Exoskeleton Technology
4.5 Robotic Actuator Energy
4.5.1 Elastic Actuators
4.5.2 General Atomics Hybrid-Electric Power Unit
4.6 Robotic Risk Mitigation
4.7 Exoskeleton Multi-Factor Solutions
4.7.1 Biometallic Materials Titanium (Ti) and its Alloys
4.8 Cognitive Science
4.9 Artificial Muscle
4.10 Standards
4.11 Regulations
5. EXOSKELETON COMPANY PROFILES
5.1 AlterG
5.1.1 AlterG: PK100 PowerKnee
5.1.2 AlterG Bionic Leg
5.1.3 AlterG M300 Customers
5.1.4 AlterG M300
5.1.5 AlterG™ Acquires Tibion Bionic Leg
5.2 Bionik Laboratories / Interactive Motion Technologies (IMT)
5.2.1 Bionik Laboratories Acquires Interactive Motion Technologies, Inc. (IMT)
5.2.2 BioNik / InMotion Robots for NHS study in the UK
5.2.3 Bionik / Interactive Motion Technologies (IMT) InMotion Robots
5.2.4 IMT Anklebot Evidence-Based Neurorehabilitation Technology
5.3 Catholic University of America Arm Therapy Robot ARMin III
5.3.1 Catholic University of America Armin Iii Project Description:
5.3.2 Catholic University of America HandSOME Hand Spring Operated Movement Enhancer
5.4 China North Industries Group Corporation (NORINCO)
5.4.1 China North Industries Corporation (NORINCO) Revenue
5.5 Cyberdyne
5.5.1 Cyberdyne Wants to Offer Robot Suit HAL in the U.S.
5.5.2 Robot Exoskeletons At Japan's Airports
5.5.3 To Offset Aging Workforce, Japan Turns to Robot-Worked Airports
5.6 Ekso Bionics
5.6.1 Esko Employees
5.6.2 Ekso Rehabilitation Robotics
5.6.3 Ekso GT
5.6.4 Ekso Fourth Quarter And Full Year 2015 Financial Results
5.6.5 Ekso Bionics Seeks To Lead The Technological Revolutions
5.6.6 Ekso Bionics Regional Presence
5.6.7 Ekso Bionics Customers
5.6.8 Ekso Able-Bodied Industrial Applications
5.6.9 Ekso Rehabilitation Robotics
5.7 Fanuc
5.7.1 Fanuc Revenue
5.7.2 Fanuc - Industrial Robot Automation Systems and Robodrill Machine Centers
5.8 Focal Meditech
5.8.1 Focal Meditech BV Collaborating Partners:
5.9 HEXORR: Hand EXOskeleton Rehabilitation Robot
5.10 Honda Motor
5.10.1 Honda Motor Revenue
5.10.2 Honda Automobile Business
5.10.3 Honda Walk Assist
5.10.4 Honda Prototype Stride Management Motorized Assist Device
5.10.5 Honda Builds Unique Transportation Exoskeleton Device Market
5.11 Interaxon
5.12 KDM
5.13 Lockheed Martin
5.13.1 Lockheed Martin First Quarter 2016 and 2015 Revenue
5.14 Lopes Gait Rehabilitation Device
5.15 MRISAR
5.16 Myomo
5.16.1 Myomo mPower 1000
5.17 Noonee
5.18 Orthocare Innovations
5.18.1 Orthocare Innovations Adaptive Systems™ For Advanced O&P Solutions.
5.18.2 Orthocare Innovations Company Highlights
5.19 Parker Hannifin
5.19.1 Parker Revenue for Fiscal 2016 and 2015 thrid Quarter Sales
5.19.2 Parker Hannifin Segment Results Fiscal 2015 Second Quarter
5.19.3 Parker and Freedom Innovations' Partnership
5.19.4 Parker Hannifin Indego License
5.20 Reha Technology
5.21 Revision Military
5.22 ReWalk Robotics
5.22.1 ReWalk Revenue
5.22.2 ReWalk First Mover Advantage
5.22.3 ReWalk Strategic Alliance with Yaskawa Electric Corporation
5.22.4 ReWalk Scalable Manufacturing Capability
5.22.5 ReWalk Leverages Core Technology Platforms
5.23 RexBionics
5.24 Robotdalen
5.25 Rostec
5.25.1 Rostec Lines Of Business
5.25.2 Rostec Corporation Objectives
5.26 RU Robots
5.27 Sarcos
5.27.1 Sarcos LC Acquires Raytheon Sarcos Unit
5.27.2 Sarcos LC Acquires Raytheon Sarcos Unit of Raytheon
5.28 Shepherd Center
5.29 Socom (U.S. Special Operations Command)
5.30 Trek Aerospace
5.31 University of Twente
5.32 United Instrument Manufacturing Corporation
5.33 Other Human Muscle Robotic Companies
5.33.1 Additional Rehabilitation Robots
5.33.2 Selected Rehabilitation Equipment Companies
5.33.3 Spinal Cord Treatment Centers in the US
ABOUT THE COMPANY
Research Methodology
Research Methodology
LIST OF TABLES AND FIGURES
Table ES-1 Industrial Exoskeleton Robot Market Driving Forces
Figure ES-2 Wearable Robot Exoskeleton Market Shares, Dollars, Worldwide, 2015
Figure ES-3 Wearable Robot, Exoskeleton Robot Market Shipments Forecasts Dollars, Worldwide, 2015-2021
Table 1-1 Industrial Wearable Exoskeletons Specific Issues
Table 2-1 Industrial Exoskeleton Robot Market Driving Forces
Figure 2-2 Wearable Robot Exoskeleton Market Shares, Dollars, Worldwide, 2015
Table 2-3 Wearable Robot Exoskeleton Market Shares, Dollars, Worldwide, 2015
Figure 2-4 Wearable Robot, Exoskeleton Robot Market Shipments Forecasts Dollars, Worldwide, 2015-2021
Table 2-5 Exoskeleton Wearable Robots: Dollars Shipments, Worldwide, 2015-2021
Table 2-6 Wearable Robots, Exoskeleton Robot Market Segments, Medical and Industrial, Dollars, Worldwide, 2015-2021
Table 2-7 Exoskeleton Robots: Units Shipments, Worldwide, 2015-2021
Figure 2-8 Lockheed Martin Exoskeleton Transfers Load Weight
Figure 2-9 Lockheed Martin Fortis Aerospace
Figure 2-10 Lockheed Martin Fortis Handtools
Figure 2-11 Daewoo Robotic Exoskeletons for Shipyard Workers in South Korea
Table 2-12 Wearable Robots, Exoskeleton Robot Market Segments, Industrial, Ship Building, Construction, Warehouse, and Manufacturing, Dollars, Worldwide, 2015-2021
Figure 2-13
Table 2-14 Robot Market Segments, Industrial, Warehouse Logistics, Cargo Unloading, Military, Surgical, Medical, Rehabilitation, Agricultural, Cleaning, Drones, Market Forecasts 2015 to 2020
Table 2-15 Wearable Robots, Exoskeleton Robot Market Segments, Medical, Quadriplegia, Multiple Sclerosis, Stroke and Cerebral Palsy, Dollars, Worldwide, 2015-2021
Table 2-16 Spinal Cord Injury Causes, Worldwide, 2014
Figure 2-17 Exoskeleton Robot Regional Market Segments, Dollars, 2015
Figure 2-18 Japanese Exoskeleton Self-Defense Forces
Figure 2-19 Daewoo Robotic Exoskeletons for Shipyard Workers in South Korea
Figure 3-1 Ekso Bionics
Figure 3-2
Figure 3-3 Esko Technology
Figure 3-4 Ekso Bionics Gait Training
Figure 3-5 Ekso Bionics Gait Training Functions
Table 3-6 Ekso Gait Training Exoskeleton Functions
Table 3-7 Ekso Gait Training Exoskeleton Functions
Figure 3-8 Ekso Bionics Step Support System
Table 3-9 Ekso Bionics Operation Modes
Figure 3-10
Figure 3-11 Ekso Bionics Bionic Suit
Figure 3-12 Rewalk-Robotics-Personal Support
Table 3-13 Lockheed Martin Human Universal Load Carrier (HULC) Features
Table 3-14 Lockheed Martin Human Universal Load Carrier (HULC) Specifications
Figure 3-15 Lockheed HULC Exoskeleton
Figure 3-16 US Navy Lockheed Martin Shipyard Exoskeleton
Figure 3-17 Lockheed HULC Lifting Device Exoskeleton
Figure 3-18 Lockheed Martin Fortis Exoskeleton Conforms to Different Body Types
Figure 3-19 Lockheed Martin Fortis Use in Aerospace Industry
Figure 3-20 Lockheed Martin Fortis
Figurer 3-21 Lockheed Martin Fortis Exoskeleton
Figure 3-22 Lockheed Martin FORTIS Exoskeleton Welding
Figure 3-23 Lockheed Martin FORTIS Exoskeleton Supporting
Figure 3-24 Berkeley Robotics Austin
Figure 3-25 Berkley Robotics and Human Engineering Laboratory ExoHiker
Figure 3-26 Berkley Robotics and Human Engineering Laboratory ExoClimber
Table 3-27 Berkley Robotics and Human Engineering Laboratory Exoskeleton
Table 5-28 Berkley Robotics and Human Engineering Laboratory Research Work
Table 5-29 Berkley Robotics and Human Engineering Laboratory Research Work
Figure 3-30 Reha-Stim Bi-Manu-Track Hand and Wrist Rehabilitation Device
Figure 3-31 Reha-Stim Gait Trainer GT I Harness
Figure 3-32 Sarcos Exoskeleton Human Support
Figure 3-33 Sarcos XOS Exoframe
Figure 3-34 Sarcos Guardian XO Capabilities
Figure 3-35 Sarcos Guardian XOS
Table 3-36 Sarcos Guardian XOS Capabilities
Figure 3-37 Sarcos Robot-as-a-Service (RaaS) Model
Figure 3-38 Sarcos Exoskeleton Developed by Raytheon
Figure 3-39 Sarcos Raytheon XOS Exoskeleton
Figure 3-40 Raytheon XOS 2: Second Generation Exoskeleton
Figure 3-41 Applications of Cyberdyne HAL
Table 3-42 Applications of Cyberdyne HAL
Figure 3-43 Berkley Robotics and Human Engineering Laboratory ExoHiker
Figure 3-44 Berkley Robotics and Human Engineering Laboratory ExoClimber
Table 3-45 Berkley Robotics and Human Engineering Laboratory Exoskeleton
Figure 3-46 Rex Bionics Exoskeleton
Figure 3-47 Rex Bionics
Figure 3-48 Noonee Assembly Line Manufacturing Exoskeleton
Figure 3-49 AlterG: PK100 PowerKnee
Figure 3-50 AlterG Bionic Neurologic And Orthopedic Therapy Leg
Figure 3-51 Tibion Bionic Leg
Table 3-52 AlterG Anti-Gravity Treadmill Precise Unweighting Technology Patient Rehabilitation Functions
Figure 3-54 ARMin III Robot For Movement Therapy Following Stroke
Table 3-55 U.S. Special Operations Command Socom First-Generation TALOS Wearable Exoskeleton Suit
Figure 3-56 Trek Aerospace Springtail/XFV Exo-Skeletor Flying Vehicle
Table 3-57 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Benefits
Table 3-58 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Monitoring
Table 3-59 HEXORR: Hand EXOskeleton Rehabilitation Robot Treatment Benefits
Table 3-60 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Force and Motion Sensor Benefits
Figure 3-61 Honda Walk Assist
Figure 3-62 Honda Walk Assist
Figure 3-63 Honda Motors Prototype Stride Management Motorized Assist Device
Figure 3-64 Revision Military - Exoskeleton Integrated Soldier Protection Vision System
Figure 3-65 Revision Military - Exoskeleton Integrated Soldier Protection System
Figure 3-66 Prototype of University to Twente in the Netherlands LOPES with 8 ACTUATED DEGREES OF FREEDOM BY MEANS OF SERIES ELASTIC ACTUATION
Figure 3-67 Prototype of University to Twente in the Netherlands LOPES with 8 ACTUATED DEGREES OF FREEDOM BY MEANS OF SERIES ELASTIC ACTUATION
Figure 3-68 China North Industries Group Assisted Lifting
Figure 3-69 Chinese Future Exoskeleton Warrior
Table 3-70 Russian Army: Combat Exoskeleton Features
Figure 3-71 Russian Exoskeleton Prototype
Figure 3-72 UK Equipping police officers with technology
Figure 3-73 UK Police Officer Exoskeleton
Figure 3-74 UK Exoskeleton Provides Compelling Law Enforcement Presence
Figure 3-75 University of Texas in Austin Robotic Upper Arm Exoskeleton
Figure 3-76 Daewoo Robotic Exoskeletons for Shipyard Workers in South Korea
Figure 3-77 Daewoo Exoskeleton 28-Kilogram Frame Weight.
Figure 3-78 Daewoo Exoskeleton Lifting
Figure 3-79 Daewoo Shipbuilding Wearable Robot Box Carrying Applications
Figure 3-80 Daewoo Shipbuilding & Marine Engineering (DSME) Wearable Robot Tank Insulation
Figure 3-81 Daewoo Insulation Boxes Used To Line The Tanks of LNG Carriers
Figure 3-82 Daewoo Shipbuilding Wearable Robot Applications
Figure 3-83 US Navy Lockheed Martin Exoskeleton
Figure 3-84 Panasonic Consumer-Grade Robotic Exoskeleton Suit ActiveLink
Figure 3-85 Panasonic Activelink Industrial Exoskeleton
Table 4-1 Industrial Exoskeleton Standards Benefits
Table 4-2 Industrial Exoskeleton Standards Functions
Figure 4-3 Industrial Robot Exoskeleton Standards
Figure 4-4 Sarcos Guardian XO Capabilities
Figure 4-5 Sarcos Guardian XOS Work Augmentation
Table 4-6 Exoskeleton System Concerns Addressed During System Design
Table 4-7 Rehabilitation Robots Software Functions
Table 5-1 AlterG Anti-Gravity Treadmillsr Features Built on differential air pressure technology
Figure 5-2 AlterG: PK100 PowerKnee
Figure 5-3 AlterG Bionic Neurologic And Orthopedic Therapy Leg
Table 5-4 AlterG Anti-Gravity Treadmillsr Target Markets
Table 5-5 AlterG Product Positioning
Figure 5-6 Selected US Regional AlterG M300 Customer CLusters
Figure 5-7 AlterG / Tibion Bionic Leg
Figure 5-8 Interactive Motor Technologies Anklebot exoskeletal robotic system Design Principals
Figure 5-9 ARMin III Robot For Movement Therapy Following Stroke
Table 5-10 China North Industries Corporation (NORINCO) Enterprise Group Product And Capital Operations Activities
Figure 5-11 Cyberdyne HAL Lower Back Support
Figure 5-12 Ekso Bionics Regional Presence
Table 5-13 FOCAL Meditech BV Products:
Table 5-14 Focal Meditech BV Collaborating Partners:
Table 5-15 HEXORR: Hand Exoskeleton Rehabilitation Robot Technology Benefits
Table 5-16 HEXORR: Hand Exoskeleton Rehabilitation Robot Technology Monitoring
Table 5-17 Honda’s Principal Automobile Products
Figure 5-18 Honda Walk Assist
Figure 5-19 Honda Motors Prototype Stride Management Motorized Assist Device
Figure 5-20 Lockheed Martin Segment Positioning
Table 5-21 Lockheed Martin's Operating Units
Figure 5-22 Noonee Chairless Chair
Figure 5-23 Parker Indego Exoskeleton
Figure 5-24 Reha G-EO Robotic Rehabilitation Device
Table 5-25 Reha Technology G-EO System
Table 5-26 Revision Military On Going Projects
Table 5-27 Rostec Lines Of Business
Table 5-28 Rostec Corporation Objectives
Table 5-29 Principal Functions Of The Corporation
Table 5-30 RUR Key Market Areas For Robotic Technologies
Figure 5-31 Sarcos Exoskeleton Human Support
Figure 5-32 Sarcos Wear Exoskeleton Timeline
Figure 5-33 Raytheon Tethered Exoskeleton
Figure 5-34 Trek Aerospace Exoskeleton
Figure 5-35 Trek Aerospace Exoskeleton Components
Table ES-1 Industrial Exoskeleton Robot Market Driving Forces
Figure ES-2 Wearable Robot Exoskeleton Market Shares, Dollars, Worldwide, 2015
Figure ES-3 Wearable Robot, Exoskeleton Robot Market Shipments Forecasts Dollars, Worldwide, 2015-2021
Table 1-1 Industrial Wearable Exoskeletons Specific Issues
Table 2-1 Industrial Exoskeleton Robot Market Driving Forces
Figure 2-2 Wearable Robot Exoskeleton Market Shares, Dollars, Worldwide, 2015
Table 2-3 Wearable Robot Exoskeleton Market Shares, Dollars, Worldwide, 2015
Figure 2-4 Wearable Robot, Exoskeleton Robot Market Shipments Forecasts Dollars, Worldwide, 2015-2021
Table 2-5 Exoskeleton Wearable Robots: Dollars Shipments, Worldwide, 2015-2021
Table 2-6 Wearable Robots, Exoskeleton Robot Market Segments, Medical and Industrial, Dollars, Worldwide, 2015-2021
Table 2-7 Exoskeleton Robots: Units Shipments, Worldwide, 2015-2021
Figure 2-8 Lockheed Martin Exoskeleton Transfers Load Weight
Figure 2-9 Lockheed Martin Fortis Aerospace
Figure 2-10 Lockheed Martin Fortis Handtools
Figure 2-11 Daewoo Robotic Exoskeletons for Shipyard Workers in South Korea
Table 2-12 Wearable Robots, Exoskeleton Robot Market Segments, Industrial, Ship Building, Construction, Warehouse, and Manufacturing, Dollars, Worldwide, 2015-2021
Figure 2-13
Table 2-14 Robot Market Segments, Industrial, Warehouse Logistics, Cargo Unloading, Military, Surgical, Medical, Rehabilitation, Agricultural, Cleaning, Drones, Market Forecasts 2015 to 2020
Table 2-15 Wearable Robots, Exoskeleton Robot Market Segments, Medical, Quadriplegia, Multiple Sclerosis, Stroke and Cerebral Palsy, Dollars, Worldwide, 2015-2021
Table 2-16 Spinal Cord Injury Causes, Worldwide, 2014
Figure 2-17 Exoskeleton Robot Regional Market Segments, Dollars, 2015
Figure 2-18 Japanese Exoskeleton Self-Defense Forces
Figure 2-19 Daewoo Robotic Exoskeletons for Shipyard Workers in South Korea
Figure 3-1 Ekso Bionics
Figure 3-2
Figure 3-3 Esko Technology
Figure 3-4 Ekso Bionics Gait Training
Figure 3-5 Ekso Bionics Gait Training Functions
Table 3-6 Ekso Gait Training Exoskeleton Functions
Table 3-7 Ekso Gait Training Exoskeleton Functions
Figure 3-8 Ekso Bionics Step Support System
Table 3-9 Ekso Bionics Operation Modes
Figure 3-10
Figure 3-11 Ekso Bionics Bionic Suit
Figure 3-12 Rewalk-Robotics-Personal Support
Table 3-13 Lockheed Martin Human Universal Load Carrier (HULC) Features
Table 3-14 Lockheed Martin Human Universal Load Carrier (HULC) Specifications
Figure 3-15 Lockheed HULC Exoskeleton
Figure 3-16 US Navy Lockheed Martin Shipyard Exoskeleton
Figure 3-17 Lockheed HULC Lifting Device Exoskeleton
Figure 3-18 Lockheed Martin Fortis Exoskeleton Conforms to Different Body Types
Figure 3-19 Lockheed Martin Fortis Use in Aerospace Industry
Figure 3-20 Lockheed Martin Fortis
Figurer 3-21 Lockheed Martin Fortis Exoskeleton
Figure 3-22 Lockheed Martin FORTIS Exoskeleton Welding
Figure 3-23 Lockheed Martin FORTIS Exoskeleton Supporting
Figure 3-24 Berkeley Robotics Austin
Figure 3-25 Berkley Robotics and Human Engineering Laboratory ExoHiker
Figure 3-26 Berkley Robotics and Human Engineering Laboratory ExoClimber
Table 3-27 Berkley Robotics and Human Engineering Laboratory Exoskeleton
Table 5-28 Berkley Robotics and Human Engineering Laboratory Research Work
Table 5-29 Berkley Robotics and Human Engineering Laboratory Research Work
Figure 3-30 Reha-Stim Bi-Manu-Track Hand and Wrist Rehabilitation Device
Figure 3-31 Reha-Stim Gait Trainer GT I Harness
Figure 3-32 Sarcos Exoskeleton Human Support
Figure 3-33 Sarcos XOS Exoframe
Figure 3-34 Sarcos Guardian XO Capabilities
Figure 3-35 Sarcos Guardian XOS
Table 3-36 Sarcos Guardian XOS Capabilities
Figure 3-37 Sarcos Robot-as-a-Service (RaaS) Model
Figure 3-38 Sarcos Exoskeleton Developed by Raytheon
Figure 3-39 Sarcos Raytheon XOS Exoskeleton
Figure 3-40 Raytheon XOS 2: Second Generation Exoskeleton
Figure 3-41 Applications of Cyberdyne HAL
Table 3-42 Applications of Cyberdyne HAL
Figure 3-43 Berkley Robotics and Human Engineering Laboratory ExoHiker
Figure 3-44 Berkley Robotics and Human Engineering Laboratory ExoClimber
Table 3-45 Berkley Robotics and Human Engineering Laboratory Exoskeleton
Figure 3-46 Rex Bionics Exoskeleton
Figure 3-47 Rex Bionics
Figure 3-48 Noonee Assembly Line Manufacturing Exoskeleton
Figure 3-49 AlterG: PK100 PowerKnee
Figure 3-50 AlterG Bionic Neurologic And Orthopedic Therapy Leg
Figure 3-51 Tibion Bionic Leg
Table 3-52 AlterG Anti-Gravity Treadmill Precise Unweighting Technology Patient Rehabilitation Functions
Figure 3-54 ARMin III Robot For Movement Therapy Following Stroke
Table 3-55 U.S. Special Operations Command Socom First-Generation TALOS Wearable Exoskeleton Suit
Figure 3-56 Trek Aerospace Springtail/XFV Exo-Skeletor Flying Vehicle
Table 3-57 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Benefits
Table 3-58 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Monitoring
Table 3-59 HEXORR: Hand EXOskeleton Rehabilitation Robot Treatment Benefits
Table 3-60 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Force and Motion Sensor Benefits
Figure 3-61 Honda Walk Assist
Figure 3-62 Honda Walk Assist
Figure 3-63 Honda Motors Prototype Stride Management Motorized Assist Device
Figure 3-64 Revision Military - Exoskeleton Integrated Soldier Protection Vision System
Figure 3-65 Revision Military - Exoskeleton Integrated Soldier Protection System
Figure 3-66 Prototype of University to Twente in the Netherlands LOPES with 8 ACTUATED DEGREES OF FREEDOM BY MEANS OF SERIES ELASTIC ACTUATION
Figure 3-67 Prototype of University to Twente in the Netherlands LOPES with 8 ACTUATED DEGREES OF FREEDOM BY MEANS OF SERIES ELASTIC ACTUATION
Figure 3-68 China North Industries Group Assisted Lifting
Figure 3-69 Chinese Future Exoskeleton Warrior
Table 3-70 Russian Army: Combat Exoskeleton Features
Figure 3-71 Russian Exoskeleton Prototype
Figure 3-72 UK Equipping police officers with technology
Figure 3-73 UK Police Officer Exoskeleton
Figure 3-74 UK Exoskeleton Provides Compelling Law Enforcement Presence
Figure 3-75 University of Texas in Austin Robotic Upper Arm Exoskeleton
Figure 3-76 Daewoo Robotic Exoskeletons for Shipyard Workers in South Korea
Figure 3-77 Daewoo Exoskeleton 28-Kilogram Frame Weight.
Figure 3-78 Daewoo Exoskeleton Lifting
Figure 3-79 Daewoo Shipbuilding Wearable Robot Box Carrying Applications
Figure 3-80 Daewoo Shipbuilding & Marine Engineering (DSME) Wearable Robot Tank Insulation
Figure 3-81 Daewoo Insulation Boxes Used To Line The Tanks of LNG Carriers
Figure 3-82 Daewoo Shipbuilding Wearable Robot Applications
Figure 3-83 US Navy Lockheed Martin Exoskeleton
Figure 3-84 Panasonic Consumer-Grade Robotic Exoskeleton Suit ActiveLink
Figure 3-85 Panasonic Activelink Industrial Exoskeleton
Table 4-1 Industrial Exoskeleton Standards Benefits
Table 4-2 Industrial Exoskeleton Standards Functions
Figure 4-3 Industrial Robot Exoskeleton Standards
Figure 4-4 Sarcos Guardian XO Capabilities
Figure 4-5 Sarcos Guardian XOS Work Augmentation
Table 4-6 Exoskeleton System Concerns Addressed During System Design
Table 4-7 Rehabilitation Robots Software Functions
Table 5-1 AlterG Anti-Gravity Treadmillsr Features Built on differential air pressure technology
Figure 5-2 AlterG: PK100 PowerKnee
Figure 5-3 AlterG Bionic Neurologic And Orthopedic Therapy Leg
Table 5-4 AlterG Anti-Gravity Treadmillsr Target Markets
Table 5-5 AlterG Product Positioning
Figure 5-6 Selected US Regional AlterG M300 Customer CLusters
Figure 5-7 AlterG / Tibion Bionic Leg
Figure 5-8 Interactive Motor Technologies Anklebot exoskeletal robotic system Design Principals
Figure 5-9 ARMin III Robot For Movement Therapy Following Stroke
Table 5-10 China North Industries Corporation (NORINCO) Enterprise Group Product And Capital Operations Activities
Figure 5-11 Cyberdyne HAL Lower Back Support
Figure 5-12 Ekso Bionics Regional Presence
Table 5-13 FOCAL Meditech BV Products:
Table 5-14 Focal Meditech BV Collaborating Partners:
Table 5-15 HEXORR: Hand Exoskeleton Rehabilitation Robot Technology Benefits
Table 5-16 HEXORR: Hand Exoskeleton Rehabilitation Robot Technology Monitoring
Table 5-17 Honda’s Principal Automobile Products
Figure 5-18 Honda Walk Assist
Figure 5-19 Honda Motors Prototype Stride Management Motorized Assist Device
Figure 5-20 Lockheed Martin Segment Positioning
Table 5-21 Lockheed Martin's Operating Units
Figure 5-22 Noonee Chairless Chair
Figure 5-23 Parker Indego Exoskeleton
Figure 5-24 Reha G-EO Robotic Rehabilitation Device
Table 5-25 Reha Technology G-EO System
Table 5-26 Revision Military On Going Projects
Table 5-27 Rostec Lines Of Business
Table 5-28 Rostec Corporation Objectives
Table 5-29 Principal Functions Of The Corporation
Table 5-30 RUR Key Market Areas For Robotic Technologies
Figure 5-31 Sarcos Exoskeleton Human Support
Figure 5-32 Sarcos Wear Exoskeleton Timeline
Figure 5-33 Raytheon Tethered Exoskeleton
Figure 5-34 Trek Aerospace Exoskeleton
Figure 5-35 Trek Aerospace Exoskeleton Components
