DUBLIN--(BUSINESS WIRE)--The "Wearable Robots, Exoskeletons: Market Shares, Strategies, and Forecasts, Worldwide, 2019-2025" report from Wintergreen Research, Inc has been added to ResearchAndMarkets.com's offering.
Exoskeleton Wearable Robots markets at $130 million in 2018 are anticipated to reach $5.2 billion by 2025. Most of the measurable revenue in 2018 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.
Exoskeletons are being developed in the U.S., China, Korea, Japan, and Europe. They are generally intended for medical, logistical and engineering purposes, due to their short range and short battery life. Most exoskeletons can operate independently for several hours. Chinese manufacturers express the hope that upgrades to exoskeletons extending the battery life could make them suitable for frontline infantry in difficult environments, including mountainous terrain.
Wearable robot exoskeleton 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 for stroke victims and people who are paralyzed. Exoskeletons are helping people relearn to move after a stroke by creating new muscle memory. Exoskeletons deliver higher quality rehabilitation, provide the base for a growth strategy for clinical facilities.
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.
Topics Covered
1. Wearable Robot Exoskeleton Market Description and Dynamics
1.1 Wearable Robot Exoskeleton Market Definition
1.2 Market Growth Drivers For Exoskeletons
1.2.1 Exoskeleton Suit
1.2.2 Running with Robots
1.2.3 Use of Video Game Technology In PT
1.2.4 Telemedicine Growing Trend In The Physical Therapy
1.3 Stroke Rehabilitation
1.3.1 Home Mobility Exoskeletons
1.3.2 Exoskeleton Able-Bodied Industrial Applications
1.4 Industrial Active and Passive Wearable Exoskeletons
1.5 Paralyzed Patients Are Walking Again With Help From Pain Stimulator
1.6 Human Augmentation
2. Exoskeleton Market Shares and Market Forecasts
2.1 Exoskeleton Market Driving Forces
2.2 Wearable Exoskeleton Market Shares and Forecasts
2.3 Wearable Medical Exoskeleton Market Shares
2.4 Medical Market Forecasts for Exoskeletons
2.5 Wearable Medical Exoskeleton Market Forecasts
2.6 Wearable Military Exoskeleton Market Shares
2.7 Wearable Military Exoskeleton Market Forecasts
2.8 Wearable Law Enforcement and First Responder Exoskeleton Market Forecasts
2.9 Wearable Industrial Exoskeleton Market Shares
2.10 Wearable Commercial Exoskeleton Market Forecasts
2.11 Exoskeleton Robots Regional Analysis
3. Wearable Robot Exoskeleton Products
3.1 Ekso
3.2 Rewalk
3.3 Lockheed Martin Exoskeleton Design
3.4 Berkeley Robotics Laboratory Exoskeletons
3.5 Bionic
3.6 Reha-Stim Harness
3.7 Exoskeleton Designed by CAR
3.8 Sarcos
3.9 Cyberdyne
3.10 Berkley Robotics Laboratory Exoskeletons
3.11 Rex Bionics
3.12 US Bionics suitX
3.13 Noonee
3.14 Hocoma
3.15 AlterG: PK100 PowerKnee
3.16 Catholic University of America Arm Therapy Robot Armin III
3.17 U.S. Special Operations Command SOCOM Wearable Exoskeleton
3.18 Revision Military Kinetic Operations Suit
3.19 HEXORR: Hand EXOskeleton Rehabilitation Robot
3.20 Honda
3.21 Revision Military - Exoskeleton Integrated Soldier Protection System
3.22 Mira Lopes Gait Rehabilitation Device
3.23 China North Industries Group Corporation (NORINCO)
3.24 Russian Army: Combat Exoskeletons by 2020
3.25 UK Exoskeleton
3.26 University of Texas in Austin: Robotic Upper-Body Rehab Exoskeleton
3.27 Daewoo Begins Testing Robotic Exoskeletons for Shipyard Workers in South Korea
3.28 Panasonic
4. Exoskeleton Technology
4.1 Safety Standards for Exoskeletons in Industry
4.2 Types of Conditions and Rehabilitation Treatment by Condition
4.3 Clinical Evidence and Reimbursement
4.4 Disease Incidence and Prevalence Analysis
4.5 Industrial Robot Exoskeleton Standards
4.6 NCMS
4.7 Exoskeleton Standards Use Environment
4.8 Exoskeleton Technology
4.9 Robotic Actuator Energy
4.10 Robotic Modules for Disability Therapy
4.11 Robotic Risk Mitigation
4.12 Elastic Actuators
4.13 Exoskeleton Multi-Factor Solutions
4.14 Cognitive Science
4.15 Artificial Muscle
4.16 Standards
4.17 Regulations
4.18 Automated Process for Rehabilitation Robots
4.19 Robotic Exoskeletons Empower Patient Rehabilitation Achievements
4.20 Seizing the Robotics Opportunity
5. Exoskeleton Company Profiles
5.1 AlterG
5.2 Berkeley Robotics Laboratory Exoskeletons
5.3 Exoskeleton Designed by CAR
5.4 Bionik Laboratories / Interactive Motion Technologies (IMT)
5.5 CAREX Upper Limb Robotic Exoskeleton
5.6 Catholic University of America Arm Therapy Robot ARMin III
5.7 China North Industries Group Corporation (NORINCO)
5.8 Cyberdyne
5.9 Ekso Bionics
5.10 Fanuc
5.11 Focal Meditech
5.12 HEXORR: Hand EXOskeleton Rehabilitation Robot
5.13 Homoca Helping Patients To Grasp The Initiative And Reach Towards Recovery
5.14 Honda Motor
5.15 Interaxon
5.16 KDM
5.17 Levitate Technologies
5.18 Lockheed Martin
5.19 Lopes Gait Rehabilitation Device
5.20 MRISAR
5.21 Myomo
5.22 Noonee
5.23 Orthocare Innovations
5.24 Panasonic
5.25 Parker Hannifin
5.26 Reha Technology
5.27 Revision Military
5.28 ReWalk Robotics
5.29 RexBionics
5.30 Robotdalen
5.31 Rostec
5.32 RU Robots
5.33 Sarcos
5.34 Shepherd Center
5.35 Socom (U.S. Special Operations Command)
5.36 SuitX
5.37 Trek Aerospace
5.38 University of Twente
5.39 United Instrument Manufacturing Corporation
5.40 Other Human Muscle Robotic Companies
For more information about this report visit https://www.researchandmarkets.com/research/w28tgm/the_exoskeleton?w=4