Table 1.
Overview of recent lower-limb rehabilitation robots.
| Groups | Devices | Researchers | Actuated DoF | Driving modes | Control strategies | Training modes |
|---|---|---|---|---|---|---|
| Lokomat [101] | Zurich Switzerland |
Two-leg DoFs | Motor drive | Position control Patient-cooperative strategy Posture control |
Passive mode Active assist mode |
|
| LokoHelp [16] | Woodway & LokoHelp Group | Two-leg DoFs | Treadmill drive, standalone driving device not required |
Trajectory tracking control |
Passive mode Active assist mode |
|
| Treadmill-based exoskeleton robots |
ALEX [17] | Banala and Aqrawal et al. from University of Delaware, US |
Seven DoFs for translations and rotation of a leg |
Motor drive | Assist-as-needed control |
Active mode |
| Lopes [18, 19] | Reneman et al. From university of Delaware, US |
Three rotational DoFs in each leg |
SEA (series elastic actuator) drive |
Impedance control |
Active mode Active assist mode |
|
| AAFO [20] | Seoul and Korea from Yonsei University |
Two motion DoFs for ankle joint |
SEA (series elastic actuator) drive |
Force/impedance control |
Active mode | |
| KAFO [21] | The Department of Mechanical Engineering of the Ottawa University |
Free motion DoFs in sagittal plane for ankle and knee |
No driver, using the location of mechanical structure and spring to provide tailwind |
Force control | Active assist mode | |
|
| ||||||
| Leg orthoses exoskeleton robots |
HAL [22] | University of Tsukuba, Japan | Full-body exoskeleton for arms, legs |
Motor drive | Autonomous control Automatic mixture control |
Active assist mode |
| BLEEX [23, 24] | Kazeroom et al. from University of California, US |
Seven DoFs for each leg in hip, knee, and ankle joints |
Hydraulic drive | EMG signal control Force control |
Passive mode | |
| Rutgers ankle [25] | Girone et al. of Rutgers University | Six DoFs ankle and foot based on a Stewart platform |
Pneumatic drive | Impedance control Force control |
Active mode Passive mode Active resist mode |
|
|
| ||||||
| Platform-based end-effector robots |
ARBOT [26, 27] | Saglia et al. from Istituto Italiano di Tecnologia, Italy |
Two ankle DoFs in plantar/dorsiflexion, inversion/eversion |
Motor drive | Position control | Passive mode Active assist mode Active resist mode |
| Parallel ankle robots [28, 29] |
Xie et al. from the University of Auckland New Zealand |
Three ankle DoFs provided by 4-axis parallel robot |
Motor drive | EMG-based evaluation and adaptive control |
Active mode Passive mode |
|
| Gait Trainer GTI [30] |
The Free University Berlin, Germany |
Two footplates for foot/leg movement |
Motor drive | Trajectory tracking control |
Passive mode Active mode |
|
|
| ||||||
| Footplate-based end-effector robots |
Haptic Walker [31] |
Hesse et al. from Charite University Hospital, Germany |
Arbitrary movement DoFs for two feet |
Motor drive | Trajectory tracking control |
Passive mode Active mode |
| G-EO Systems [32] |
Reha Technology AG, Switzerland | Two footplates for walking and climbing DoFs |
Motor drive | Position control Trajectory tracking control |
Active assist mode | |