1,092 research outputs found
Autonomous Locomotion Mode Transition Simulation of a Track-legged Quadruped Robot Step Negotiation
Multi-modal locomotion (e.g. terrestrial, aerial, and aquatic) is gaining
increasing interest in robotics research as it improves the robots
environmental adaptability, locomotion versatility, and operational
flexibility. Within the terrestrial multiple locomotion robots, the advantage
of hybrid robots stems from their multiple (two or more) locomotion modes,
among which robots can select from depending on the encountering terrain
conditions. However, there are many challenges in improving the autonomy of the
locomotion mode transition between their multiple locomotion modes. This work
proposed a method to realize an autonomous locomotion mode transition of a
track-legged quadruped robot steps negotiation. The autonomy of the
decision-making process was realized by the proposed criterion to comparing
energy performances of the rolling and walking locomotion modes. Two climbing
gaits were proposed to achieve smooth steps negotiation behaviours for energy
evaluation purposes. Simulations showed autonomous locomotion mode transitions
were realized for negotiations of steps with different height. The proposed
method is generic enough to be utilized to other hybrid robots after some
pre-studies of their locomotion energy performances
The aerodynamic effects of wing–wing interaction in flapping insect wings
We employed a dynamically scaled mechanical model of the small fruit fly Drosophila melanogaster (Reynolds number 100–200) to investigate force enhancement due to contralateral wing interactions during stroke reversal (the 'clap-and-fling'). The results suggest that lift enhancement during clap-and-fling requires an angular separation between the two wings of no more than 10–12°. Within the limitations of the robotic apparatus, the clap-and-fling augmented total lift production by up to 17%, but depended strongly on stroke kinematics. The time course of the interaction between the wings was quite complex. For example, wing interaction attenuated total force during the initial part of the wing clap, but slightly enhanced force at the end of the clap phase. We measured two temporally transient peaks of both lift and drag enhancement during the fling phase: a prominent peak during the initial phase of the fling motion, which accounts for most of the benefit in lift production, and a smaller peak of force enhancement at the end fling when the wings started to move apart. A detailed digital particle image velocimetry (DPIV) analysis during clap-and-fling showed that the most obvious effect of the bilateral 'image' wing on flow occurs during the early phase of the fling, due to a strong fluid influx between the wings as they separate. The DPIV analysis revealed, moreover, that circulation induced by a leading edge vortex (LEV) during the early fling phase was smaller than predicted by inviscid two-dimensional analytical models, whereas circulation of LEV nearly matched the predictions of Weis-Fogh's inviscid model at late fling phase. In addition, the presence of the image wing presumably causes subtle modifications in both the wake capture and viscous forces. Collectively, these effects explain some of the changes in total force and lift production during the fling. Quite surprisingly, the effect of clap-and-fling is not restricted to the dorsal part of the stroke cycle but extends to the beginning of upstroke, suggesting that the presence of the image wing distorts the gross wake structure throughout the stroke cycle
Females prefer extra-pair males that are older and better hunters
Age of male is an important cue in mate selection, including extra-pair copulations; different phenotypic and behavioural traits are known to be age related. Paternity studies show that older males predominate as fathers of extra-pair young. It remains unclear if females actively choose older males because they possess high quality traits or because older males are more successful in coercing fertile females. We experimentally provided mounted males of different age (yearling vs. adult) of great grey shrike Lanius excubitor with nuptial gifts of different quality (vole vs. cricket) and observed reactions of females and their social partners. Females strongly preferred older males with energy-rich nuptial gifts. The reactions of females’ social partner to the extra-pair male did not differ significantly amongst experimental groups. However, males responded to the reaction of their mates and male aggressive behaviour increased when their mate showed an interest in an intruder
Miniature mobile sensor platforms for condition monitoring of structures
In this paper, a wireless, multisensor inspection system for nondestructive evaluation (NDE) of materials is described. The sensor configuration enables two inspection modes-magnetic (flux leakage and eddy current) and noncontact ultrasound. Each is designed to function in a complementary manner, maximizing the potential for detection of both surface and internal defects. Particular emphasis is placed on the generic architecture of a novel, intelligent sensor platform, and its positioning on the structure under test. The sensor units are capable of wireless communication with a remote host computer, which controls manipulation and data interpretation. Results are presented in the form of automatic scans with different NDE sensors in a series of experiments on thin plate structures. To highlight the advantage of utilizing multiple inspection modalities, data fusion approaches are employed to combine data collected by complementary sensor systems. Fusion of data is shown to demonstrate the potential for improved inspection reliability
How aggressive interactions with biomimetic agents optimize reproductive performances in mass-reared males of the Mediterranean fruit fly
Mass-rearing procedures of insect species, often used in biological control and Sterile Insect Technique, can reduce the insects competitiveness in foraging, dispersal, and mating. The evocation of certain behaviours responsible to induce specific neuroendocrine products may restore or improve the competitiveness of mass-reared individuals. Herein, we used a mass-reared strain of Ceratitis capitata as model organism. C. capitata is a polyphagous pest exhibiting territorial displays that are closely related to its reproductive performance. We tested if the behaviour of C. capitata males could be altered by hybrid aggressive interactions with a conspecific-mimicking robotic fly, leading to more competitive individuals in subsequent mating events. Aggressive interactions with the robotic fly had a notable effect on subsequent courtship and mating sequences of males that performed longer courtship displays compared to naïve individuals. Furthermore, previous interactions with the robotic fly produced a higher mating success of males. Reproductive performances of C. capitata males may be improved by specific octopaminergic neurones activated during previous aggressive interactions with the robotic fly. This study adds fundamental knowledge on the potential role of specific neuro-behavioural processes in the ecology of tephritid species and paves the way to innovative biotechnological control methods based on robotics and bionics
Distribution of sound pressure around a singing cricket: radiation pattern and asymmetry in the sound field
Male field crickets generate calls to attract distant females through tegminal stridulation: the
rubbing together of the overlying right wing which bears a file of cuticular teeth against the
underlying left wing which carries a sclerotised scraper. During stridulation, specialised areas of
membrane on both wings are set into oscillating vibrations to produce acoustic radiation. The
location of females is unknown to the calling males and thus increasing effective signal range in all
directions will maximise transmission effectiveness. However, producing an omnidirectional sound
field of high sound pressure levels may be problematic due to the mechanical asymmetry found in
this sound generation system. Mechanical asymmetry occurs by the right wing coming to partially
cover the left wing during the closing stroke phase of stridulation. As such, it is hypothesised that the
sound field on the left-wing side of the animal will contain lower sound pressure components than
on the right-wing side as a result of this coverage. This hypothesis was tested using a novel method
to accurately record a high resolution, three dimensional mapping of sound pressure levels around
restrained Gryllus bimaculatus field crickets singing under pharmacological stimulation. The results
indicate that a bilateral asymmetry is present across individuals, with greater amplitude components
present in the right wing side of the animal. Individual variation in sound pressure to either the right
or left-wing side is also observed. However, statistically significant differences in bilateral sound field
asymmetry as presented here may not affect signalling in the field
Safety experiments for small robots investigating the potential of soft materials in mitigating the harm to the head due to impacts
There is a growing interest in social robots to be considered in the therapy
of children with autism due to their effectiveness in improving the outcomes.
However, children on the spectrum exhibit challenging behaviors that need to be
considered when designing robots for them. A child could involuntarily throw a
small social robot during meltdown and that could hit another person's head and
cause harm (e.g. concussion). In this paper, the application of soft materials
is investigated for its potential in attenuating head's linear acceleration
upon impact. The thickness and storage modulus of three different soft
materials were considered as the control factors while the noise factor was the
impact velocity. The design of experiments was based on Taguchi method. A total
of 27 experiments were conducted on a developed dummy head setup that reports
the linear acceleration of the head. ANOVA tests were performed to analyze the
data. The findings showed that the control factors are not statistically
significant in attenuating the response. The optimal values of the control
factors were identified using the signal-to-noise (S/N) ratio optimization
technique. Confirmation runs at the optimal parameters (i.e. thickness of 3 mm
and 5 mm) showed a better response as compared to other conditions. Designers
of social robots should consider the application of soft materials to their
designs as it help in reducing the potential harm to the head
Ultrasonic sensor platforms for non-destructive evaluation
Robotic vehicles are receiving increasing attention for use in Non-Destructive Evaluation (NDE), due to their attractiveness in terms of cost, safety and their accessibility to areas where manual inspection is not practical. A reconfigurable Lamb wave scanner, using autonomous robotic platforms is presented. The scanner is built from a fleet of wireless miniature robotic vehicles, each with a non-contact ultrasonic payload capable of generating the A0 Lamb wave mode in plate specimens. An embedded Kalman filter gives the robots a positional accuracy of 10mm. A computer simulator, to facilitate the design and assessment of the reconfigurable scanner, is also presented. Transducer behaviour has been simulated using a Linear Systems approximation (LS), with wave propagation in the structure modelled using the Local Interaction Simulation Approach (LISA). Integration of the LS and LISA approaches were validated for use in Lamb wave scanning by comparison with both analytical techniques and more computationally intensive commercial finite element/diference codes. Starting with fundamental dispersion data, the work goes on to describe the simulation of wave propagation and the subsequent interaction with artificial defects and plate boundaries. The computer simulator was used to evaluate several imaging techniques, including local inspection of the area under the robot and an extended method that emits an ultrasonic wave and listens for echos (B-Scan). These algorithms were implemented in the robotic platform and experimental results are presented. The Synthetic Aperture Focusing Technique (SAFT) was evaluated as a means of improving the fidelity of B-Scan data. It was found that a SAFT is only effective for transducers with reasonably wide beam divergence, necessitating small transducers with a width of approximately 5mm. Finally, an algorithm for robot localisation relative to plate sections was proposed and experimentally validated
Perception in real and artificial insects: a robotic investigation of cricket phonotaxis
The aim of this thesis is to investigate a methodology for studying percep¬
tual systems by building artificial ones. It is proposed that useful results can be
obtained from detailed robotic modelling of specific sensorimotor mechanisms in
lower animals. By looking at the sensory control of behaviour in simple biological
organisms, and in working robots, it is argued that proper appreciation of the
physical interaction of the system with the environment and the task is essential
for discovering how perceptual mechanisms function. Although links to biology,
and concern with perceptual competence, are fields of growing interest in Artificial
Intelligence, much of the current research fails to adequately address these issues,
as the model systems being built do not represent real sensorimotor problems.By analyzing what is required for a model of a system to contribute to ex¬
plaining that system, a particular approach to modeling perceptual systems is
suggested. This involves choosing an appropriate target system to model, building
a system that validly represents the target with respect to a particular hypothesis,
and properly evaluating the behaviour of the model system to draw conclusions
about the target. The viability and potential contribution of this approach is
demonstrated in the design, implementation and evaluation of a mobile robot
model of a hypothesised mechanism for phonotaxis in the cricket.The result is a robot that successfully locates a specific sound source under a
variety of conditions, with a range of behaviour that resembles the cricket in many
ways. This provides some support for the hypothesis that the neural mechanism
for phonotaxis in crickets does not involve separate processing for recognition and
location of the signal, as is generally supposed. It also shows the importance of un¬
derstanding the physical interaction of the system's structure with its environment
in devising and implementing perceptual systems. Both these results vindicate the
proposed methodology
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