Abstract-This paper presents the design principles for highly efficient legged robots, the implementation of the principles in the design of the MIT Cheetah, and the analysis of the high-speed trotting experimental results. The design principles were derived by analyzing three major energy-loss mechanisms in locomotion: heat losses from the actuators, friction losses in transmission, and the interaction losses caused by the interface between the system and the environment. Four design principles that minimize these losses are discussed: employment of high torque density motors, energy regenerative electronic system, low loss transmission, and a low leg inertia. These principles were implemented in the design of the MIT Cheetah; the major design features are large gap diameter motors, regenerative electric motor drivers, single-stage low gear transmission, dual coaxial motors with composite legs, and the differential actuated spine. The experimental results of fast trotting are presented; the 33kg robot runs at 22 km/h (6 m/s). The total power consumption from the battery pack was 973 watts and resulted in a total cost of transport of 0.5, which rivals running animals' at the same scale. The 76% of total energy consumption is attributed to heat loss from the motor, and the 24% is used in mechanical work, which is dissipated as interaction loss as well as friction losses at the joint and transmission.
Abstract-This paper presents implementation of a highly dynamic running gait with a hierarchical controller on the MIT Cheetah ⇤ . The developed controller enables a high-speed running up to 6 m/s (Froude number of Fr ⇡ 7.34) incorporating proprioceptive feedback and programmable virtual leg compliance of the MIT Cheetah. To achieve a stable and fast trot gait, we applied three control strategies: 1) programmable virtual leg compliance that provides instantaneous reflexes to external disturbance and facilitates the self-stabilizing shown in the passive dynamics of locomotion; 2) tunable stance-trajectory design, intended to adjust impulse at each foot-end in the stance phase in a high speed trot-running according to the equilibriumpoint hypothesis; and 3) a gait-pattern modulation that imposes a desired cyclic gait pattern taking cues from proprioceptive touch-down feedback. Based on three strategies, the controller is hierarchically structured. The control parameters for forward speeds, a specific gait pattern, and desired leg trajectories are managed by a high-level controller. It consists of both a gait pattern modulator with a proprioceptive leg touch-down detection and a leg-trajectory generator using a Bèzier curve and a tunable amplitude sinusoidal wave. Instead of employing physical spring/dampers in the robot's leg, the programmable virtual leg compliance is realized using proprioceptive impedance control in individual low-level leg controllers.To verify the developed controller, a robot dynamic simulator is constructed based on the model parameters of the MIT Cheetah. The controller parameters are tuned with the simulator to achieve self-stability ,and then applied to the MIT Cheetah in an experimental environment. Using leg kinematics and applied motor current feedbacks, the MIT Cheetah achieved a stable trot-running gait in the sagittal plane.
Exercise intensity of exoskeleton-assisted walking in patients with spinal cord injury (SCI) has been reported as moderate. However, the cardiorespiratory responses to long-term exoskeleton-assisted walking have not been sufficiently investigated. We investigated the cardiorespiratory responses to 10 weeks of exoskeleton-assisted walking training in patients with SCI. Chronic nonambulatory patients with SCI were recruited from an outpatient clinic. Walking training with an exoskeleton was conducted three times per week for 10 weeks. Oxygen consumption and heart rate (HR) were measured during a 6-min walking test at pre-, mid-, and post-training. Exercise intensity was determined according to the metabolic equivalent of tasks (METs) for SCI and HR relative to the HR reserve (%HRR). Walking efficiency was calculated as oxygen consumption divided by walking speed. The exercise intensity according to the METs (both peak and average) corresponded to moderate physical activity and did not change after training. The %HRR demonstrated a moderate (peak %HRR) and light (average %HRR) exercise intensity level, and the average %HRR significantly decreased at post-training compared with mid-training (31.6 ± 8.9% to 24.3 ± 7.3%, p = 0.013). Walking efficiency progressively improved after training. Walking with an exoskeleton for 10 weeks may affect the cardiorespiratory system in chronic patients with SCI.
This paper presents a demonstration of the trot-to-gallop transition and subsequent
stable gallop in a robotic quadruped. The MIT Cheetah I, a planar quadruped platform for
high-speed running, achieves these tasks with a speed of 3.2 m/s (Froude number of 2.1) on
a treadmill. The controller benefits from clues from biological findings and it
incorporates (1) a gait pattern modulation that imposes predefined gait patterns with a
proprioceptive touchdown feedback, (2) tunable equilibrium-point foot-end trajectories for
four limbs that intentionally modulate ground reaction forces, and (3) programmable leg
compliance that provides instantaneous reflexes to leg–ground interaction. An inertial
measurement unit sensor is integrated with the controller in order to regulate leg angles
of attack at touchdown. We reduce the dimension of the control parameters which describe
temporal/spatial characteristics of quadruped locomotion, and the values are tuned via
dynamic simulation and then experiment. Given a pre-defined virtual leg compliance and a
desired angle of attack of legs, the equilibrium-point foot-end trajectories and phase
relationships between four legs for stable trot and gallop gaits are found independently.
We propose a simple throw-and-catch gait transition strategy which connects two stable
limit cycles, the trot and the gallop, by linearly varying control parameters during the
transition period. Successful gait transition is achieved in both simulation and
experiment. Comprehensive analysis on the characteristics of the MIT Cheetah I
experimental trot-to-gallop transition is provided. The phase portraits imply that stable
limit cycles are achieved with the proposed controller in both trot and gallop, which
enables the trot-to-gallop gait transition at high speed.
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