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1. By
Chun-Lung Lim
Jay Hatcher
Clay Harris
2. Humanoid Robotic Hardware Biped Humanoid Robot Group - Kato/Takanishi Laboratory & Waseda University
WABIAN-2 - (WAseda BIpedal humANiod-No.2)
Artificial Muscle Begins to Breathe
Sensor Networks for Humanoids (Repliee Q2)
3. WL-1 (Waseda Leg Series) The artificial lower-limb WL-1 was constructed on the basis of a human’s leg mechanism in 1967
Investigation of the fundamental functions of biped locomotion
4. WL-3 Constructed with electro-hydraulic servo-actuator in 1969
Achieved a human-like motion in a swing phase and a stance phase, and a standing and sitting motion
5. WL-5 Eleven mechanical degrees of freedom; two x five DOF legs and one DOF trunk
could change the direction by using a program control (1971)
6. WABOT-1 the world’s first full-scale anthropomorphic robot
Could communicate with a human in Japanese
Measure the distances and directions of objects using external receptors such as artificial ears and eyes
Hydraulically powered, it uses disproportionately large feet for stability
realized “static walking” in 1973
7. WL-9DR achieved quasi-dynamic walking
used a 16-bit microcomputer as its controller
ten mechanical degrees of freedom
8. WL-10R constructed by the rotary type servo-actuators and carbon-fiber reinforced plastic in 1983
achieved forward and backward walking, turning on the plane
9. WL-10RD achieved a complete dynamic walking on the plane with the step time of 1.3 s/step
dynamic walking on uneven terrain such stairs and inclined planes was realized with a step time of 2.5 s/step
10. WL-12 hydraulic biped having an upper body and a two-degrees-of-freedom waist (1986)
dynamic biped walking was realized under external forces of unknown environments and on unknown walking surfaces
11. WL-12RDIII walked in unknown paths, and stairs in a human residential environment
Also used trunk motion for balance and for compensating moment generated by leg movement
12. WABIAN (WAseda BIpedal humANoid) Dynamic forward and backward walking
Collaborative work with humans
Dancing
Carrying a Load
Emotional Walking
Total of 35 DOF
13. WABIAN-2 Total of 41 DOF
Height: 153 cm
Weight:
64.5 kg w/Ni-H batteries
60.0 kg without
6-axis Force Sensors
Photo Sensor
DC Servo Motors
On Board Computer
14. WABIAN-2 Control System
15. Human Like Walking with 6 vs. 7 DOF
16. Waist Movement 2-DOF (Roll, Yaw) in the waist enables more human-like walking motions. This new mechanism has an advantage which allows the robot to walk with knee stretched position due to the independent orientation of trunk movement.
17. Movement Examples Moving knees with feet on the floor
Upper body movement
Moving arms and legs with feet and hands fixed
Conventional walking
Stretch walking
Walking assisted
18. Artificial Muscle Begins to Breathe Fuel cell muscle. (Top) Oxygen dissolved in water transfers charge (assisted by the platinum catalyst) to paper made of carbon nanotubes (CNT). The nanotube film (black) expands as a result of the charging (3), causing it to bend as it expands relative to the platinum/carbon/ionomer layer (dark gray). (Bottom) The bending is reversed by closing the circuit to a hydrogen electrode, which neutralizes the charge. The counter electrode is a carbon bilayer-platinum catalyst-Nafion membrane electrode assembly shown in "exploded view." Fuel cell muscle. (Top) Oxygen dissolved in water transfers charge (assisted by the platinum catalyst) to paper made of carbon nanotubes (CNT). The nanotube film (black) expands as a result of the charging (3), causing it to bend as it expands relative to the platinum/carbon/ionomer layer (dark gray). (Bottom) The bending is reversed by closing the circuit to a hydrogen electrode, which neutralizes the charge. The counter electrode is a carbon bilayer-platinum catalyst-Nafion membrane electrode assembly shown in "exploded view."
19. Tensile actuator. (Left) Nickel titanium shape memory alloys can also be used as actuators. The NiTi wire is coated with platinum catalyst. (Right) When dissolved hydrogen and oxygen react on the platinum coating to produce water, the resulting heat induces a phase change in the NiTi leading to contraction and force generation (2). Both actuator reactions are reversible. Tensile actuator. (Left) Nickel titanium shape memory alloys can also be used as actuators. The NiTi wire is coated with platinum catalyst. (Right) When dissolved hydrogen and oxygen react on the platinum coating to produce water, the resulting heat induces a phase change in the NiTi leading to contraction and force generation (2). Both actuator reactions are reversible.
20. Fig. 2. Continuously shorted fuel-cell muscle based on a NiTi shape-memory alloy. (A) Schematic illustration, with cutaway to reveal details, of the fuel-powered artificial muscle mounted in the dynamic mechanical analyzer used for measurements. (B) Actuator strain versus time during exposure of the chemically powered actuator to a mixture of N2, 2.5% by volume hydrogen and 50% oxygen (red curves) and during exposure to pure oxygen (blue curves). (C) Actuator strain versus time for different volume percents of H2 for the experiment in (B). The insert shows the dependence of actuator strain on the H2 volume % in the fuel
This stress-generation capability is 500 times that which is typical for human skeletal muscle (0.3 MPa), whereas the percent stroke is 25% that of this natural muscle
Fig. 2. Continuously shorted fuel-cell muscle based on a NiTi shape-memory alloy. (A) Schematic illustration, with cutaway to reveal details, of the fuel-powered artificial muscle mounted in the dynamic mechanical analyzer used for measurements. (B) Actuator strain versus time during exposure of the chemically powered actuator to a mixture of N2, 2.5% by volume hydrogen and 50% oxygen (red curves) and during exposure to pure oxygen (blue curves). (C) Actuator strain versus time for different volume percents of H2 for the experiment in (B). The insert shows the dependence of actuator strain on the H2 volume % in the fuel
This stress-generation capability is 500 times that which is typical for human skeletal muscle (0.3 MPa), whereas the percent stroke is 25% that of this natural muscle
21. Main Advantages high–energy-density fuels (hydrogen, methanol, or formic acid) may be used resulting in much longer operating times
Honda’s humanoid, ASIMO, only lasts 45 minutes on its batteries
WABIAN 2 only lasts around 30 minutes
Lightweight compared to Servo Motors and Batteries
22. Omnidirectional Sensor
