A Survey on Mechanical Solutions for Hybrid Mobile Robots
Abstract
:1. Introduction
2. Classification of Locomotion
2.1. Aquatic Locomotion
2.2. Aerial Locomotion
2.3. Terrestrial Locomotion
2.4. Hybrid Locomotion
- Reconfigurable multimodal robots, when they are characterized by two or more locomotion modes performed by the same mechatronic system. The reconfiguration strategy of these class of robots must be carefully studied to reduce “dead” times, when the robot changes from a configuration to another.
- Non-reconfigurable multimodal robots, when the different locomotion modes are independent from each other. In this case, it is possible to define hybrid motion strategies when both modes are performed together to optimize navigation and performance.
2.5. Technology Readiness
- TRL 1 – basic principles observed
- TRL 2 – technology concept formulated
- TRL 3 – experimental proof of concept
- TRL 4 – technology validated in laboratory
- TRL 5 – technology validated in relevant environment
- TRL 6 – technology demonstrated in relevant environment
- TRL 7 – system prototype demonstration in operational environment
- TRL 8 – system complete and qualified
- TRL 9 – actual system proven in operational environment.
- Level 1 – Hypothetical commercial proposition
- Level 2 – Commercial trial
- Level 3 – Commercial scale up
- Level 4 – Multiple commercial applications
- Level 5 – Market competition driving widespread deployment
- Level 6 – “Bankable” grade asset class.
3. Terrestrial Hybrid Robots
4. Amphibious Hybrid Robots
5. Aerial Hybrid Robots
Case Study: HeritageBot
- Optimal navigation: instead of planning HeritageBot path from one waypoint to the following one by considering a single locomotion mode, an energy cost function can be defined to take into account the energy consumption of the path by using: flight only; walking only; a combination of the two. Thus, an optimal path can be defined as the one with the minimal energy cost. Even if walking has a lower cost overall, an aerial path can be more convenient (or even the only possible way) in case of large obstacles on the way.
- Dynamic balancing: the helices can be used to generate aerodynamic lift to balance the quadruped robot in case of slipping or similar losses of balance (e.g., landslides on the ground where the robot is walking). Moreover, an aerodynamic drag force can be generated to help the robot “walk” on surfaces with high inclination by keeping the feet contacting the ground.
- Improved payload: in case of intervention and sample collection, an aerodynamic lift can be used to increase the payload of the system without overloading the linear actuators of the legs.
6. Discussion
- Main and secondary modes of locomotion: one of the main design trends behind hybrid mobile robot is to have a primary mode of locomotion that is usually more efficient or performing, and a secondary mode that is used only to overcome obstacles. An example of this design is given by wheeled/legged mobile robots.
- Reconfigurable mode of locomotion: many hybrid robots use a single mode of locomotion (e.g., legs, or helices) that works in more than one environment with minimal change. For examples, helices can be used to generate thrust in water, and lift for flying, or legs can swim and walk.
- Independent locomotion modes: robots with two or more independent locomotory systems are usually either designed to use them one at a time. Little research has been done on how multiple modes can interact and collaborate.
- Applications: while the most common designs are usually task-oriented, many bio-inspired robots are developed without a target application, but only to prove the feasibility of new designs (e.g., most of the flapping wings robot). Even if those robots are interesting, the lack of focus limits them to low TRLs.
- Performance index: a general index to represent the performance of the robot, as for example energy consumption and efficiency during different motion modes, is not available. Thus, it is difficult to compare robots with different modes of motion even when they move in similar environments.
7. Conclusions
Funding
Conflicts of Interest
References
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AREAS | TYPES | MODES | TRL | CRI |
---|---|---|---|---|
AQUATIC | Swimming | Fins | 1–6 | - |
Undulatory motion | 1–6 | - | ||
Jet propulsion | 7–9 | - | ||
Helices | 7–9 | 1–2 | ||
Benthic | Legs | 1–3 | - | |
Suction cups | 1–3 | - | ||
Crawling | 1–3 | - | ||
Rolling | 1–3 | - | ||
Surface | Sails | 1–6 | - | |
Fins | 1–6 | - | ||
Helices | 1–6 | 1–2 | ||
Jet propulsion | 1–6 | - | ||
Surface striding | 1–3 | - | ||
AERIAL | Active flying | Insect wings | 1–3 | - |
Bird wings | 1–3 | - | ||
Helices | 7–9 | 3–4 | ||
Jet propulsion | 7–9 | 1–4 | ||
Gliding | Gliding surfaces | 1–3 | - | |
Ballooning | Balloons | 1–3 | - | |
TERRESTRIAL | Walking/running/jumping | Legs | 4–9 | 1–2 |
Sliding | Skates | 1–3 | - | |
Crawling | Peristalsis | 1–4 | - | |
Slithering | 1–4 | - | ||
Climbing | Surface adhesion | 1–3 | - | |
Brachiation | 1–3 | - | ||
Rotation | Wheels | 7–9 | 3–4 | |
Tracks | 7–9 | 3–4 | ||
Rolling | 4–6 | 1–2 |
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Russo, M.; Ceccarelli, M. A Survey on Mechanical Solutions for Hybrid Mobile Robots. Robotics 2020, 9, 32. https://doi.org/10.3390/robotics9020032
Russo M, Ceccarelli M. A Survey on Mechanical Solutions for Hybrid Mobile Robots. Robotics. 2020; 9(2):32. https://doi.org/10.3390/robotics9020032
Chicago/Turabian StyleRusso, Matteo, and Marco Ceccarelli. 2020. "A Survey on Mechanical Solutions for Hybrid Mobile Robots" Robotics 9, no. 2: 32. https://doi.org/10.3390/robotics9020032
APA StyleRusso, M., & Ceccarelli, M. (2020). A Survey on Mechanical Solutions for Hybrid Mobile Robots. Robotics, 9(2), 32. https://doi.org/10.3390/robotics9020032