JoVE Journal > Neuroscience
Summary
Abstract
Introduction
Protocol
Results
Discussion
Disclosures
Acknowledgements
Materials
References
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신경과학

Böcek kontrollü Robot: Bir Mobil Robot Platformu bir Böcek Koku izleme Yeteneği değerlendirin

Published: December 19, 2016
doi:
10.3791/54802
, ,
1Research Center for Advanced Science and Technology,The University of Tokyo

Summary

Bir koku kaynağı yerelleştirilmesine yeteneği böcek hayatta kalmak için gerekli olan ve yapay koku izleme için geçerli olması bekleniyor. Böcek kontrollü robot gerçek bir silkmoth tarafından tahrik ve bir robot platform üzerinden böceklerin koku izleme yeteneği değerlendirmek için bize sağlar edilir.

Abstract

Robotic odor source localization has been a challenging area and one to which biological knowledge has been expected to contribute, as finding odor sources is an essential task for organism survival. Insects are well-studied organisms with regard to odor tracking, and their behavioral strategies have been applied to mobile robots for evaluation. This “bottom-up” approach is a fundamental way to develop biomimetic robots; however, the biological analyses and the modeling of behavioral mechanisms are still ongoing. Therefore, it is still unknown how such a biological system actually works as the controller of a robotic platform. To answer this question, we have developed an insect-controlled robot in which a male adult silkmoth (Bombyx mori) drives a robot car in response to odor stimuli; this can be regarded as a prototype of a future insect-mimetic robot. In the cockpit of the robot, a tethered silkmoth walked on an air-supported ball and an optical sensor measured the ball rotations. These rotations were translated into the movement of the two-wheeled robot. The advantage of this “hybrid” approach is that experimenters can manipulate any parameter of the robot, which enables the evaluation of the odor-tracking capability of insects and provides useful suggestions for robotic odor-tracking. Furthermore, these manipulations are non-invasive ways to alter the sensory-motor relationship of a pilot insect and will be a useful technique for understanding adaptive behaviors.

Introduction

Autonomous robots capable of finding an odor source can be important for the safety and security of society. They can be used for the detection of disaster victims, of drugs or explosive materials at an airport, and of hazardous material spills or leaks in the environment. At present, we rely entirely on well-trained animals (e.g., dogs) for these tasks, and robotic odor source localization has been strongly expected to relieve the workload of these animals. Finding an odor source is a challenging task for robots because odorants are distributed intermittently in an atmosphere1; therefore, continuous sampling of the odor concentration gradient is not always possible. Thus, a search strategy using intermittent odor cues is necessary for the achievement of robotic odor source localization2-4.

Odor source localization is essential for organism survival and includes tasks such as finding food, mating partners, and sites for oviposition. To overcome the difficulty in tracking patchy distributed odorants, organisms have evolved various behavioral strategies consisting of two fundamental behaviors: moving upstream during odor reception and cross-stream during cessation of odor reception5,6. These reactive strategies have been well-documented in insects and further combined with other modalities, such as wind direction and vision5-8. The insect behavioral models have also been useful examples for robotics3,9-11, in which behavioral algorithms or neural circuit models are implemented into mobile robots for the evaluation of odor source localization abilities10,12-15. From biomimetic perspectives, this “bottom-up” approach is certainly a fundamental way to develop biomimetic robots. However, the bottom-up approach is not a shortcut to obtaining a useful search strategy, because biological analyses are still ongoing, and the modeling of the sensory-motor systems behind insect behaviors has not been completed. Therefore, it is still unknown how such a biological system actually works as a controller of a robotic platform.

In this article, we demonstrate the protocol of a straightforward “top-down” approach to develop an odor-tracking mobile robot controlled by a biological system16,17. The robot is controlled by a real insect and can be regarded as a prototype of future insect-mimetic robots. In the robot’s cockpit, a tethered adult male silkmoth (Bombyx mori) walked on an air-supported ball in response to the female sex pheromone, which was delivered to each antenna through air suction tubes. The ball rotations caused by the walking of the onboard moth were measured by an optical sensor and were translated into the movement of the two-wheeled robot. The advantage of this “hybrid” approach is that experimenters can investigate how the insect sensory-motor system works on the robotic platform where a pilot insect is in a closed loop between the robot and a real odor circumstance. The manipulation of the robotic hardware alters the closed loop; therefore, the insect-controlled robot is a useful platform for both engineers and biologists. For engineering, the robot represents the first steps of applying a biological model to meet the requirements for robotic tasks. For biology, the robot is an experimental platform for studying sensory-motor control under a closed loop.

Protocol

1. Deneysel Hayvan Onların eclosion kadar erkek silkmoths ve pupa (B. mori) tutmak için bir plastik kutu hazırlayın. Put kağıt altındaki havlu ve kutu (Şekil 1A) iç duvarı etrafında karton parçaları. Not: eclosion (Şekil 1A) sırasında kanatlarını uzatırken yetişkin güveler tutmak için karton parçaları gereklidir. Put erkek silkmoth (Bombyx mor i) kutusuna pupa ve 16 saat altında eclosion kadar bir ku…

Representative Results

Biz burada bir koku kaynağının başarılı lokalizasyonu için gerekli olan böcek kontrollü robotun temel özelliklerini sunuyoruz. robot ve silkmoths, koku verme sisteminin etkinliği ve doğru ikili koku alma ve görsel verilerin önemini karşılaştırılması incelenmiştir. Özgürce yürüyüş kelebekler ve böcek kontrollü robot arasındaki koku izleme davranışları karşılaştırılması Şekil 10A</…

Discussion

Bir silkmoth tarafından robotun başarılı bir şekilde kontrol için en önemli noktalar güve hava destekli topa düzgün yürümek izin ve stabil topun dönmesi ölçme. Bu nedenle, silkmoth tethering ve uygun pozisyonda topa üzerine monte Bu protokol kritik adımlar vardır. eki ya da topa güve uygunsuz konumlandırılması güve uygunsuz yapışma normal yürüme davranışını bozan ve / veya topun dönmesi ölçmek için optik sensör bir başarısızlık nedenleri üzerinde doğal olmayan baskı, neden olac…

Disclosures

The authors have nothing to disclose.

Acknowledgements

We thank Shigeru Matsuyama for providing purified bombykol. This work was supported by the Japan Society for the Promotion of Science KAKENHI (grant numbers 22700197 and 24650090) and the Human Frontier Science Program (HFSP).

Materials

Male adult silkmoth
 (Bombyx mori)		 Rear from eggs, or purchase as pupae.
Incubator Panasonic MIR-254 Store pupae or adult silkmoths at a constant temperature, 238 L.
Plastic box Sunplatec O-3 Store pupae or adult silkmoths, 299 × 224 × 62 mm L × W × H.
Copper wire 2-mm diameter for the attachment. Any rigid bar can be used as an alternative for making the attachment to tether a silkmoth. 
Plastic sheet Kokuyo VF-1420N Sold as overhead projector film with thickness of 0.1 mm. Use at the tip of the attachment.
Forceps As one 5SA Remove scales on the thorax.
Adhesive Konishi G17 Bond a silkmoth to the attachment.
Insect-controlled robot Custom Bearing an air-supported treadmill, an optical sensor, custom-built AVR-based microcontroller boards, and two DC brushless motors. It is powered by 8 × AA and 3 × 006P batteries.
Microcontroller Atmel ATMEGA8 A component of the insect-controlled robot.
DC blower Nidec A34342-55 A component of the insect-controlled robot for floating a ball in an air-supported treadmill. 
DC fan Minebea 1606KL-04W-B50 A component of the insect-controlled robot for suctioning air containing an odor.
Optical mouse sensor Agilent technologies HDNS-2000 A component of the insect-controlled robot, obtained from an optical mouse (M-GUWSRSV, Elecom, Japan).
Brushless motor Maxon EC-45 A component of the insect-controlled robot for driving a wheel.
White polystyrene ball A component of the insect-controlled robot. Diameter 50 mm, mass approximately 2 g.
Bombykol:
 (E,Z)-10,12-hexadecadien-1-ol		 Shin-Etsu chemical Custom synthesis.
n-hexane Wako 085-00416 Solvent for bombykol.
Wind tunnel Custom Pulling-air type, sized 1800 × 900 × 300 mm L × W × H.
BioSignal program Custom A program to establish serial communication between the insect-controlled robot and a PC via Bluetooth. Used for sending commands to start/stop the robot or configuring its motor properties. 
Camcorder Sony HDR-XR520V Capture robot movements.
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References

  1. Murlis, J., Jones, C. D. Fine-scale structure of odor plumes in relation to insect orientation to distant pheromone and other attractant sources. Physiol Entomol. 6, 71-86 (1981).
  2. Vergassola, M., Villermaux, E., Shraiman, B. I. ‘Infotaxis’ as a strategy for searching without gradients. Nature. 445, 406-409 (2007).
  3. Kowadlo, G., Russell, R. A. Robot Odor Localization: A Taxonomy and Survey. The International Journal of Robotics Research. 27, 869-894 (2008).
  4. Hernandez Bennetts, V., Lilienthal, A. J., Neumann, P. P., Trincavelli, M. Mobile robots for localizing gas emission sources on landfill sites: is bio-inspiration the way to go. Frontiers in neuroengineering. 4, 20 (2011).
  5. Vickers, N. J. Mechanisms of animal navigation in odor plumes. Biol Bull. 198, 203-212 (2000).
  6. Willis, M. A. Chemical plume tracking behavior in animals and mobile robots. Navigation. 55, 127-135 (2008).
  7. Carde, R. T., Willis, M. A. Navigational strategies used by insects to find distant, wind-borne sources of odor. J Chem Ecol. 34, 854-866 (2008).
  8. Frye, M. A. Multisensory systems integration for high-performance motor control in flies. Curr Opin Neurobiol. 20, 347-352 (2010).
  9. Russell, R. A. Survey of robotic applications for odor-sensing technology. The International Journal of Robotics Research. 20, 144-162 (2001).
  10. Russell, R. A., Bab-Hadiashar, A., Shepherd, R. L., Wallace, G. G. A comparison of reactive robot chemotaxis algorithms. Robot Auton Syst. 45, 83-97 (2003).
  11. Ishida, H., Nakamoto, T., Moriizumi, T., Kikas, T., Janata, J. Plume-tracking robots: a new application of chemical sensors. Biol Bull. 200, 222-226 (2001).
  12. Webb, B., Harrison, R. R., Willis, M. A. Sensorimotor control of navigation in arthropod and artificial systems. Arthropod Struct Dev. 33, 301-329 (2004).
  13. Kanzaki, R. How does a microbrain generate adaptive behavior. Int Congr Ser. 1301, 7-14 (2007).
  14. Kanzaki, R., Ando, N., Sakurai, T., Kazawa, T. Understanding and reconstruction of the mobiligence of insects employing multiscale biological approaches and robotics. Adv Robotics. 22, 1605-1628 (2008).
  15. Ravel, N., et al. Multiphasic on/off pheromone signalling in moths as neural correlates of a search strategy. Plos One. 8, 61220 (2013).
  16. Emoto, S., Ando, N., Takahashi, H., Kanzaki, R. Insect-controlled robot-evaluation of adaptation ability. J Robot Mechatronics. 19, 436-443 (2007).
  17. Ando, N., Emoto, S., Kanzaki, R. Odour-tracking capability of a silkmoth driving a mobile robot with turning bias and time delay. Bioinspir Biomim. 8, 016008 (2013).
  18. Gatellier, L., Nagao, T., Kanzaki, R. Serotonin modifies the sensitivity of the male silkmoth to pheromone. J Exp Biol. 207, 2487-2496 (2004).
  19. Ando, N., Kanzaki, R. A simple behaviour provides accuracy and flexibility in odour plume tracking – the robotic control of sensory-motor coupling in silkmoths. J. Exp. Biol. 218, 3845-3854 (2015).
  20. Kaissling, K. E., Beidler, L. M. Insect olfaction. Handbook of Sensory Physiology Vol. 4. , 351-431 (1971).
  21. Kanzaki, R., Sugi, N., Shibuya, T. Self-generated zigzag turning of Bombyx mori males during pheromone-mediated upwind walking. Zool Sci. 9, 515-527 (1992).
  22. Takasaki, T., Namiki, S., Kanzaki, R. Use of bilateral information to determine the walking direction during orientation to a pheromone source in the silkmoth Bombyx mori. J Comp Physiol. A. 198, 295-307 (2012).
  23. Kanzaki, R. Coordination of wing motion and walking suggests common control of zigzag motor program in a male silkworm moth. J Comp Physiol A. 182, 267-276 (1998).
  24. Pansopha, P., Ando, N., Kanzaki, R. Dynamic use of optic flow during pheromone tracking by the male silkmoth, Bombyx mori. J Exp Biol. 217, 1811-1820 (2014).
  25. Loudon, C., Koehl, M. A. R. Sniffing by a silkworm moth: Wing fanning enhances air penetration through and pheromone interception by antennae. J. Exp. Biol. 203, 2977-2990 (2000).
  26. Lebedev, M. A., Nicolelis, M. A. L. Brain-machine interfaces: past, present and future. Trends Neurosci. 29, 536-546 (2006).
  27. Ejaz, N., Peterson, K. D., Krapp, H. G. An experimental platform to study the closed-loop performance of brain-machine interfaces. Journal of visualized experiments : JoVE. , (2011).
  28. Minegishi, R., Takashima, A., Kurabayashi, D., Kanzaki, R. Construction of a brain-machine hybrid system to evaluate adaptability of an insect. Robot Auton Syst. 60, 692-699 (2012).
  29. Martinez, D., Arhidi, L., Demondion, E., Masson, J. B., Lucas, P. Using insect electroantennogram sensors on autonomous robots for olfactory searches. Journal of visualized experiments : JoVE. , e51704 (2014).
  30. Ortiz, L. I. . A mobile electrophysiology board for autonomous biorobotics. , (2006).
  31. Bohil, C. J., Alicea, B., Biocca, F. A. Virtual reality in neuroscience research and therapy. Nat Rev Neurosci. 12, 752-762 (2011).
  32. Dombeck, D. A., Reiser, M. B. Real neuroscience in virtual worlds. Curr Opin Neurobiol. 22, 3-10 (2012).
  33. Roth, E., Sponberg, S., Cowan, N. J. A comparative approach to closed-loop computation. Curr Opin Neurobiol. 25, 54-62 (2014).
  34. Leinweber, M., et al. Two-photon calcium imaging in mice navigating a virtual reality environment. Journal of visualized experiments : JoVE. , e50885 (2014).
  35. Takalo, J., et al. A fast and flexible panoramic virtual reality system for behavioural and electrophysiological experiments. Sci Rep. 2, 324 (2012).
  36. Bahl, A., Ammer, G., Schilling, T., Borst, A. Object tracking in motion-blind flies. Nat Neurosci. 16, 730-738 (2013).
  37. Bellmann, D., et al. Optogenetically Induced olfactory stimulation in Drosophila larvae reveals the neuronal basis of odor-aversion behavior. Front Behav Neurosci. 4, 27 (2010).
  38. Gaudry, Q., Hong, E. J., Kain, J., de Bivort, B. L., Wilson, R. I. Asymmetric neurotransmitter release enables rapid odour lateralization in Drosophila. Nature. 493, 424-428 (2013).
  39. Tabuchi, M., et al. Pheromone responsiveness threshold depends on temporal integration by antennal lobe projection neurons. Proc Natl Acad Sci U S A. 110, 15455-15460 (2013).
  40. Schulze, A., et al. Dynamical feature extraction at the sensory periphery guides chemotaxis. Elife. 4, 06694 (2015).
  41. Duistermars, B. J., Chow, D. M., Frye, M. A. Flies require bilateral sensory input to track odor gradients in flight. Curr Biol. 19, 1301-1307 (2009).
  42. Gomez-Marin, A., Duistermars, B. J., Frye, M. A., Louis, M. Mechanisms of odor-tracking: multiple sensors for enhanced perception and behavior. Front Cell Neurosci. 4, 6 (2010).
  43. Sakurai, T., et al. A single sex pheromone receptor determines chemical response specificity of sexual behavior in the silkmoth Bombyx mori. Plos Genet. 7, (2011).
  44. Tripathy, S. J., et al. Odors pulsed at wing beat frequencies are tracked by primary olfactory networks and enhance odor detection. Front Cell Neurosci. 4, 1 (2010).
  45. Daly, K. C., Kalwar, F., Hatfield, M., Staudacher, E., Bradley, S. P. Odor detection in Manduca sexta is optimized when odor stimuli are pulsed at a frequency matching the wing beat during flight. Plos One. 8, 81863 (2013).
  46. Szyszka, P., Gerkin, R. C., Galizia, C. G., Smith, B. H. High-speed odor transduction and pulse tracking by insect olfactory receptor neurons. Proc Natl Acad Sci USA. 111, 16925-16930 (2014).
  47. Harvey, D., Lu, T. F., Keller, M. Odor sensor requirements for an insect inspired plume tracking mobile robot. Proceedings of’The 2006 IEEE International Conference on Robotics and Biomimetics. , 130-135 (2006).

Tags

AI-controlled RobotInsect-controlled RobotOdor-tracking RobotSilkmoth RobotBiomimetic Robot NavigationSensory-motor ControlBiomedical Robotics
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Ando, N., Emoto, S., Kanzaki, R. Insect-controlled Robot: A Mobile Robot Platform to Evaluate the Odor-tracking Capability of an Insect. J. Vis. Exp. (118), e54802, doi:10.3791/54802 (2016).
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