biomechanik:modellierung:mm4:tbm
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| biomechanik:modellierung:mm4:tbm [05.07.2017 16:55] – Maziar Sharbafi | biomechanik:modellierung:mm4:tbm [28.11.2022 00:58] (aktuell) – Externe Bearbeitung 127.0.0.1 | ||
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| ====== Template-based modeling ====== | ====== Template-based modeling ====== | ||
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| + | ^Module-Icon |TBM Template-based modeling | | ||
| + | ^Event |none | | ||
| + | ^Author |[[http:// | ||
| + | ^Requirements |Module Kin 1-3 and Dyn 1-4 | | ||
| + | ^teaching time |45 min | | ||
| + | ^Last modified |11.7.2017 | | ||
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| + | | [[biomechanik: | ||
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| Legged locomotion in biological systems is a complex and not fully understood problem. A | Legged locomotion in biological systems is a complex and not fully understood problem. A | ||
| great progress to simplify understanding locomotion dynamics and control was made by introducing | great progress to simplify understanding locomotion dynamics and control was made by introducing | ||
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| gaits. | gaits. | ||
| - | Before describing template based modeling we first summarize the challenges on robotics specially legged robots. See this [[https:// | + | Before describing template based modeling we first summarize the challenges on robotics specially legged robots. See the following |
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| + | {{ youtube> | ||
| Inspired from what Russ said the challneges of the current technologies in robotics can be summarized in Fig. 1. Expensive robots reauiring highe precision sensors and actuators, with complex and accurate controller which needs precise design and manufacturing requiring huge amunt of energy are too far from biological locomotors. | Inspired from what Russ said the challneges of the current technologies in robotics can be summarized in Fig. 1. Expensive robots reauiring highe precision sensors and actuators, with complex and accurate controller which needs precise design and manufacturing requiring huge amunt of energy are too far from biological locomotors. | ||
| - | {{: | + | {{: |
| Figure 1. Challenges of the current technologies in robotics. | Figure 1. Challenges of the current technologies in robotics. | ||
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| Our understanding of legged locomotion is based on two fundamental ingredients shown in Fig. 3: Mechanics and control. The locomotor body (mechanics) need to be optimized to simplify and fit to control. The neural system in human body plays the role of the controller which matches the body properties.This combination needs to be robust against any uncertainties, | Our understanding of legged locomotion is based on two fundamental ingredients shown in Fig. 3: Mechanics and control. The locomotor body (mechanics) need to be optimized to simplify and fit to control. The neural system in human body plays the role of the controller which matches the body properties.This combination needs to be robust against any uncertainties, | ||
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| - | Fig. 3. Basic elements in elgged | + | Fig. 3. Basic elements in legged |
| In order to design a legged system, we use the trilogy shown in Fig. 4. First, we learn from nature (biology) to extract basic principles. The next step is building the models to verify the basic concepts and develop new methods. Finally, the design and control approaches need to be implemented on the hardware. One of the most useful applications of studying legged locomotion from a biomechanical point of view is implementing the ideas on new assistive devices like prostheses and orthoses. | In order to design a legged system, we use the trilogy shown in Fig. 4. First, we learn from nature (biology) to extract basic principles. The next step is building the models to verify the basic concepts and develop new methods. Finally, the design and control approaches need to be implemented on the hardware. One of the most useful applications of studying legged locomotion from a biomechanical point of view is implementing the ideas on new assistive devices like prostheses and orthoses. | ||
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| Different steps in designing a legged system from the biomechanical point of view and its application in daily life. | Different steps in designing a legged system from the biomechanical point of view and its application in daily life. | ||
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| In the first group, simple models are used to describe selected basic features of legged locomotion. Such models are not considering the details of dynamics and control of the systems. Basic elements in physics like mass, spring, damper, and pendulum are employed to represent the fundamental behavior of the locomotor. Spring Loaded Inverted Pendulum (SLIP) and Inverted Pendulum (IP) are two of such template models. | In the first group, simple models are used to describe selected basic features of legged locomotion. Such models are not considering the details of dynamics and control of the systems. Basic elements in physics like mass, spring, damper, and pendulum are employed to represent the fundamental behavior of the locomotor. Spring Loaded Inverted Pendulum (SLIP) and Inverted Pendulum (IP) are two of such template models. | ||
| - | The second group comprises of detailed dynamic models including body mechanics, actuators, sensors, and controller. For example neuromuscular models | + | The second group comprises of detailed dynamic models including body mechanics, actuators, sensors, and controller. For example neuromuscular models |
| - | In (Full & Koditsceck 1999), the concept of template & anchor was introduced which connected these two groups (See Fig. 1) | + | In [Full99], the concept of template & anchor was introduced which connected these two groups (See Fig. 1) |
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| - | Figure 1. Template & anchor concept from (Full & Koditcheck 1999). | + | Figure 1. Template & anchor concept from [Full99]. |
| === Locomotor subfunction concept === | === Locomotor subfunction concept === | ||
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| orthoses, and prostheses). | orthoses, and prostheses). | ||
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| Figure 5. Three locomotor subfunctions: | Figure 5. Three locomotor subfunctions: | ||
| - | With this approach, we can identify | + | With this approach, we can identify the relation between different locomotor sub-functions e.g., between balance and stance (using stance |
| - | the relation between different locomotor sub-functions e.g., between balance and stance (using stance | + | |
| force for tuning balance control) or balance and swing (two joint hip muscles can support the swing leg | force for tuning balance control) or balance and swing (two joint hip muscles can support the swing leg | ||
| control relating it to the upper body posture) and implement the concept of modular control based on | control relating it to the upper body posture) and implement the concept of modular control based on | ||
| locomotor sub-functions with a limited exchange of sensory information on several hardware platforms | locomotor sub-functions with a limited exchange of sensory information on several hardware platforms | ||
| (legged robots, exoskeleton). | (legged robots, exoskeleton). | ||
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| + | ==== Exercise: ==== | ||
| + | - Explain the template & Anchor concept in 5 sentences with your words. | ||
| + | - Another template model LLS (called lateral leg spring) mentioned in [Full99] from [Schmitt00]. Find this model and explain it in one paragraph. | ||
| + | - What are the three basic locomotor subfunctions? | ||
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| + | ==== References ==== | ||
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| + | [Geyer10] Geyer, H., & Herr, H. (2010). A muscle-reflex model that encodes principles of legged mechanics produces human walking dynamics and muscle activities. IEEE Transactions on neural systems and rehabilitation engineering, | ||
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| + | [Full99] RJ Full and DE Koditschek. Templates and anchors: neuromechanical hypotheses of legged locomotion | ||
| + | on land. Journal of Experimental Biology, 202(23): | ||
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| + | [Schmitt00] Schmitt, J., & Holmes, P. (2000). Mechanical models for insect locomotion: dynamics and stability in the horizontal plane I. Theory. Biological cybernetics, | ||
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biomechanik/modellierung/mm4/tbm.1499266555.txt.gz · Zuletzt geändert: 28.11.2022 00:57 (Externe Bearbeitung)