Your search keyword '"insect antenna"' showing total 12 results

1. An insect-inspired bionic sensor for tactile localisation and material classification with state-dependent modulation

Author

Luca ePatanè, Sven eHellbach, André Frank Krause, Paolo eArena, and Volker eDürr

Subjects

tactile sense, Spiking Network, bionic sensor, forward model, insect antenna, material classification, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Insects carry a pair of antennae on their head: multimodal sensory organs that serve a wide range of sensory-guided behaviours. During locomotion, antennae are involved in near-range orientation, for example in detecting, localising, probing and negotiating obstacles.Here we present a bionic, active tactile sensing system inspired by insect antennae. It comprises an actuated elastic rod equipped with a terminal acceleration sensor. The measurement principle is based on the analysis of damped harmonic oscillations registered upon contact with an object. The dominant frequency of the oscillation is extracted to determine the distance of the contact point along the probe, and basal angular encoders allow tactile localisation in a polar coordinate system. Finally, the damping behaviour of the registered signal is exploited to determine the most likely material.The tactile sensor is tested in four approaches with increasing neural plausibility: First, we show that peak extraction from the Fourier spectrum is sufficient for tactile localisation with position errors below 1%. Also, the damping property of the extracted frequency is used for material classification. Second, we show that the Fourier spectrum can be analysed by an Artificial Neural Network which can be trained to decode contact distance and to classify contact materials. Thirdly, we show how efficiency can be improved by band-pass filtering the Fourier spectrum by application of non-negative matrix factorisation. This reduces the input dimension by 95% while reducing classification performance by 8% only. Finally, we replace the FFT by an array of spiking neurons with gradually differing resonance properties, such that their spike rate is a function of the input frequency. We show that this network can be applied to detect tactile contact events of a wheeled robot, and how detrimental effects of robot velocity on antennal dynamics can be suppressed by state-dependent modulation of the input signals.

Published

2012

2. Active tactile sampling by an insect in a step-climbing paradigm

Author

André Frank Krause and Volker eDürr

Subjects

tactile sense, active touch, Carausius, climbing, insect antenna, inter-joint coordination, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Many insects actively explore their near-range environment with their antennae. Stick insects (Carausius morosus) rhythmically move their antennae during walking and respond to antennal touch by repetitive tactile sampling of the object. Despite its relevance for spatial orientation, neither the spatial sampling patterns nor the kinematics of antennation behaviour in insects are understood. Here we investigate unrestrained bilateral sampling movements during climbing of steps. The main objectives are: (1) How does the antennal contact pattern relate to particular object features? (2) How are the antennal joints coordinated during bilateral tactile sampling? We conducted motion capture experiments on freely climbing insects, using steps of different height. Tactile sampling was analyzed at the level of antennal joint angles. Moreover, we analysed contact patterns on the surfaces of both the obstacle and the antenna itself.Before the first contact, both antennae move in a broad, mostly elliptical exploratory pattern. After touching the obstacle, the pattern switches to a narrower and faster movement, caused by higher cycle frequencies and lower cycle amplitudes in all joints. Contact events were divided into wall- and edge contacts. Wall contacts occurred mostly with the distal third of the flagellum, which is flexible, whereas edge contacts often occurred proximally, where the flagellum is stiff.The movement of both antennae was found to be coordinated, exhibiting bilateral coupling of functionally analogous joints (e.g., left head-scape joint with right scape-pedicel joint) throughout tactile sampling. In comparison, bilateral coupling between homologous joints (e.g., both head-scape joints) was significantly weaker. Moreover, inter-joint coupling was significantly weaker during the contact episode than before. In summary, stick insects show contact-induced changes in frequency, amplitude and inter-joint coordination during tactile sampling of climbed obstacles.

Published

2012

3. Active tactile sampling by an insect in a step-climbing paradigm.

Author

Krause, André F. and Dürr, Volker

Subjects

PHASMIDA, ANTENNAE (Biology), INSECT kinematics, STAIR climbing, TOUCH

Abstract

Many insects actively explore their near-range environment with their antennae. Stick insects (Carausius morosus) rhythmically move their antennae during walking and respond to antennal touch by repetitive tactile sampling of the object. Despite its relevance for spatial orientation, neither the spatial sampling patterns nor the kinematics of antennation behavior in insects are understood. Here we investigate unrestrained bilateral sampling movements during climbing of steps. The main objectives are: (1) How does the antennal contact pattern relate to particular object features? (2) How are the antennal joints coordinated during bilateral tactile sampling? We conducted motion capture experiments on freely climbing insects, using steps of different height. Tactile sampling was analyzed at the level of antennal joint angles. Moreover, we analyzed contact patterns on the surfaces of both the obstacle and the antenna itself. Before the first contact, both antennae move in a broad, mostly elliptical exploratory pattern. After touching the obstacle, the pattern switches to a narrower and faster movement, caused by higher cycle frequencies and lower cycle amplitudes in all joints. Contact events were divided into wall- and edge-contacts. Wall contacts occurred mostly with the distal third of the flagellum, which is flexible, whereas edge contacts often occurred proximally, where the flagellum is stiff. The movement of both antennae was found to be coordinated, exhibiting bilateral coupling of functionally analogous joints [e.g., left head-scape (HS) joint with right scape-pedicel (SP) joint] throughout tactile sampling. In comparison, bilateral coupling between homologous joints (e.g., both HS joints) was significantly weaker. Moreover, inter-joint coupling was significantly weaker during the contact episode than before. In summary, stick insects show contact-induced changes in frequency, amplitude and inter-joint coordination during tactile sampling of climbed obstacles. [ABSTRACT FROM AUTHOR]

Published

2012

4. Active tactile exploration for adaptive locomotion in the stick insect.

Author

Schütz, Christoph and Dürr, Volker

Abstract

Insects carry a pair of actively movable feelers that supply the animal with a range of multimodal information. The antennae of the stick insect Carausius morosus are straight and of nearly the same length as the legs, making them ideal probes for near-range exploration. Indeed, stick insects, like many other insects, use antennal contact information for the adaptive control of locomotion, for example, in climbing. Moreover, the active exploratory movement pattern of the antennae is context- dependent. The first objective of the present study is to reveal the significance of antennal contact information for the efficient initiation of climbing. This is done by means of kinematic analysis of freely walking animals as they undergo a tactually elicited transition from walking to climbing. The main findings are that fast, tactually elicited re-targeting movements may occur during an ongoing swing movement, and that the height of the last antennal contact prior to leg contact largely predicts the height of the first leg contact. The second objective is to understand the context-dependent adaptation of the antennal movement pattern in response to tactile contact. We show that the cycle frequency of both antennal joints increases after obstacle contact. Furthermore, inter-joint coupling switches distinctly upon tactile contact, revealing a simple mechanism for context-dependent adaptation. [ABSTRACT FROM AUTHOR]

Published

2011

5. Templates and Anchors for Antenna-Based Wall Following in Cockroaches and Robots.

Author

Jusuk Lee, Sponberg, Simon N., Loh, Owen Y., Lamperski, Andrew G., Full, Robert J., and Cowan, Noah J.

Subjects

*ROBOTICS, *ANTENNAS (Electronics), *NEUROPHYSIOLOGY, *COCKROACHES, *INSECT behavior, *SENSES

Abstract

The interplay between robotics and neuromechanics facilitates discoveries in both fields: nature provides roboticists with design ideas, while robotics research elucidates critical features that confer performance advantages to biological systems. Here, we explore a system particularly well suited to exploit the synergies between biology and robotics: high-speed antenna-based wall following of the American cockroach (Periplaneta americana). Our approach integrates mathematical and hardware modeling with behavioral and neurophysiological experiments. Specifically, we corroborate a prediction from a previously reported wall-following template—the simplest model that captures a behavior—that a cockroach antenna-based controller requires the rate of approach to a wall in addition to distance, e.g., in the form of a proportional-derivative (PD) controller. Neurophysiological experiments reveal that important features of the wall-following con- troller emerge at the earliest stages of sensory processing, namely in the antennal nerve. Furthermore, we embed the template in a robotic platform outfitted with a bio-inspired antenna. Using this system, we successfully test specific PD gains (up to a scale) fitted to the cockroach behavioral data in a "real-world" setting, lending further credence to the surprisingly simple notion that a cockroach might implement a PD controller for wall following. Finally, we embed the template in a simulated lateral-leg-spring (LLS) model using the center of pressure as the control input. Importantly, the same PD gains fitted to cockroach behavior also stabilize wall following for the LLS model. [ABSTRACT FROM AUTHOR]

Published

2008

6. Active tactile exploration and tactually induced turning in tethered walking stick insects.

Author

Berendes V and Dürr V

Subjects

Animals, Locomotion, Insecta, Touch

Abstract

Many animals use their tactile sense for active exploration and tactually guided behaviors such as near-range orientation. In insects, tactile sensing is often intimately linked to locomotion, resulting in the orchestration of several concurrent active movements, including turning of the entire body, rotation of the head, and searching or sampling movements of the antennae. The present study aims at linking the sequence of tactile contact events to associated changes of all three kinds of these active movements (body, head and antennae). To do so, we chose the Indian stick insect Carausius morosus, an organism commonly used to study sensory control of locomotion. Methodologically, we combined recordings of walking speed, heading, whole-body kinematics and antennal contact sequences during stationary, tethered walking and controlled presentation of an 'artificial twig' for tactile exploration. Our results show that object presentation episodes as brief as 5 s are sufficient to allow for a systematic investigation of tactually induced turning behavior in walking stick insects. Animals began antennating the artificial twig within 0.5 s, and altered the beating fields of both antennae in a position-dependent manner. This change was mainly carried by a systematic shift of the head-scape joint movement and accompanied by associated changes in contact likelihood, contact location and sampling direction of the antennae. The turning tendency of the insect also depended on stimulus position, whereas the active, rhythmic head rotation remained unaffected by stimulus presentation. We conclude that the azimuth of contact location is a key parameter of active tactile exploration and tactually induced turning in stick insects., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2022. Published by The Company of Biologists Ltd.)

Published

2022

7. Tactile conditioning and movement analysis of antennal sampling strategies in honey bees (Apis mellifera L.)

Author

Mujagic, Samir, Würth, Simon, Hellbach, Sven, and Dürr, Volker

Subjects

Arthropod Antennae, Honey bee, Proboscis extension response, Behavior, Animal, Insect antenna, Touch, Tactile sampling, Animals, Conditioning, Operant, Bees, Motion capture, Neuroscience, Conditioning

Abstract

Honey bees (Apis mellifera L.) are eusocial insects and well known for their complex division of labor and associative learning capability(1, 2). The worker bees spend the first half of their life inside the dark hive, where they are nursing the larvae or building the regular hexagonal combs for food (e.g. pollen or nectar) and brood(3). The antennae are extraordinary multisensory feelers and play a pivotal role in various tactile mediated tasks(4), including hive building(5) and pattern recognition(6). Later in life, each single bee leaves the hive to forage for food. Then a bee has to learn to discriminate profitable food sources, memorize their location, and communicate it to its nest mates(7). Bees use different floral signals like colors or odors(7, 8), but also tactile cues from the petal surface(9) to form multisensory memories of the food source. Under laboratory conditions, bees can be trained in an appetitive learning paradigm to discriminate tactile object features, such as edges or grooves with their antennae(10, 11, 12, 13). This learning paradigm is closely related to the classical olfactory conditioning of the proboscis extension response (PER) in harnessed bees(14). The advantage of the tactile learning paradigm in the laboratory is the possibility of combining behavioral experiments on learning with various physiological measurements, including the analysis of the antennal movement pattern.

Published

2012

8. Biomechanics of the stick insect antenna: Damping properties and structural correlates of the cuticle

Author

Jan-Henning Dirks and Volker Dürr

Subjects

Arthropod Antennae, Carausius morosus, Insecta, Materials science, Double pendulum, Biomedical Engineering, Arthropod cuticle, Flagellum, biomechanics, Damper, Contact force, Biomaterials, Deflection (engineering), Hemolymph, Pressure, Animals, Desiccation, Mechanical Phenomena, damping, biology, business.industry, insect antenna, Biomechanics, Structural engineering, Mechanics, biology.organism_classification, tactile sensing, Biomechanical Phenomena, Flagella, Mechanics of Materials, cuticle, business

Abstract

The antenna of the Indian stick insect Carausius morosus is a highly specialized near-range sensory probe used to actively sample tactile cues about location, distance or shape of external objects in real time. The length of the antenna's flagellum is 100 times the diameter at the base, making it a very delicate and slender structure. Like the rest of the insect body, it is covered by a protective exoskeletal cuticle, making it stiff enough to allow controlled, active, exploratory movements and hard enough to resist damage and wear. At the same time, it is highly flexible in response to contact forces, and returns rapidly to its straight posture without oscillations upon release of contact force. Which mechanical adaptations allow stick insects to unfold the remarkable combination of maintaining a sufficiently invariant shape between contacts and being sufficiently compliantduring contact? What role does the cuticle play? Our results show that, based on morphological differences, the flagellum can be divided into three zones, consisting of a tapered cone of stiff exocuticle lined by an inner wedge of compliant endocuticle. This inner wedge is thick at the antenna's base and thin at its distal half. The decay time constant after deflection, a measure that indicates strength of damping, is much longer at the base (tau > 25 ms) than in the distal half (tau < 18 ms) of the flagellum. Upon experimental desiccation, reducing mass and compliance of the endocuticle, the flagellum becomes under-damped. Analyzing the frequency components indicates that the flagellum can be abstracted with the model of a double pendulum with springs and dampers in both joints. We conclude that in the stick-insect antenna the cuticle properties described are structural correlates of damping, allowing for a straight posture in the instant of a new contact event, combined with a maximum of flexibility.

Published

2011

9. Coupling of insect antennae to field-effect transistors for biochemical sensing

Author

Schroth, P., Schöning, M. J., Schütz, S., Malkoc, Ü., Steffen, A., Marso, Michel, Hummel, H. E., Kordoš, P., Lüth, H., Schroth, P., Schöning, M. J., Schütz, S., Malkoc, Ü., Steffen, A., Marso, Michel, Hummel, H. E., Kordoš, P., and Lüth, H.

Abstract

A bioelectronic interface based on the coupling of an intact insect antenna to a field-e effct transistor (FET) has been realised in a whole-beetle BioFET (Biologically sensitive FET) and an isolated-antenna BioFET configuration. The intrinsic BioFET characteristics, such as current-voltage curves, transconductance and signal-to-noise ratio clearly depend on the chip layout. Therefore, the experiments were performed with three di erent gate geometries: linear shape (5 um x 100 um), U shape (5 um x 1000 um) and meander shape (10 um x 6000 um). The BioFET allows the determination of the `green-leaf odour' Z-3-hexen-l-ol down to the low ppb concentration range. Thus, the detection of plant damages is possible with this novel kind of biosensor.

Published

1999

10. Contour-Net: a model for tactile contour-tracing and shape-recognition

Author

Nalin Harischandra, Thierry Hoinville, André Frank Krause, and Volker Dürr

Subjects

Artificial neural network, tactile sense, Orientation (computer vision), Computer science, business.industry, insect antenna, Sampling (statistics), Data point, Position (vector), Robustness (computer science), Computer vision, Artificial intelligence, tactile sampling, bio-inspired, business, Tactile sensor, shape recognition, Initial and terminal objects

Abstract

We propose Contour-Net as a bio-inspired model for rhythmic movement control of a pair of insectoid feelers, able to successively sample the contour of arbitrarily shaped objects. Initial object contact initiates a smooth transition from a large-amplitude, low-frequency searching behaviour to a local, small-amplitude and high frequency sampling behaviour. Both behavioural states are defined by the parameters of a Hopf Oscillator. Subsequent contact signals trigger a 180o phase-forwarding of the oscillator, resulting in repeated sampling of the object. The local sampling behaviour effectively serves as a contour-tracing method with high robustness, even for complicated shapes. Collected contour data points can be directly fed into an artificial neural network to classify the shape of an object. Given a sufficiently large training dataset, tactile shape recognition can be achieved in a position-, orientation- and size-invariant manner. Only minimal pre-processing (normalisation) of contour data points is required.

11. The insect antenna is not a molecular sieve

Author

Mankin, R. W. and Mayer, M. S.

Published

1984

12. Nanometre-Range Acoustic Sensitivity in Male and Female Mosquitoes

Author

Göpfert, Martin C. and Robert, Daniel

Published

2000