wing shape
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2022 ◽  
Author(s):  
Laurence Kedward ◽  
Christian B. Allen ◽  
T. Rendall ◽  
Daniel J. Poole

Sensors ◽  
2021 ◽  
Vol 22 (1) ◽  
pp. 168
Author(s):  
Huifeng Wu ◽  
Lei Liang ◽  
Hui Wang ◽  
Shu Dai ◽  
Qiwei Xu ◽  
...  

FBG shape sensors based on soft substrates are currently one of the research focuses of wing shape reconstruction, where soft substrates and torque are two important factors affecting the performance of shape sensors, but the related analysis is not common. A high-precision soft substrates shape sensor based on dual FBGs is designed. First, the FBG soft substrate shape sensor model is established to optimize the sensor size parameters and get the optimal solution. The two FBG cross-laying method is adopted to effectively reduce the influence of torque, the crossover angle between the FBGs is 2α, and α = 30° is selected as the most sensitive angle to the torquer response. Second, the calibration test platform of this shape sensor is built to obtain the linear relationship among the FBG wavelength drift and curvature, rotation radian loaded vertical force and torque. Finally, by using the test specimen shape reconstruction test, it is verified that this shape sensor can improve the shape reconstruction accuracy, and that its reconstruction error is 6.13%, which greatly improves the fit of shape reconstruction. The research results show that the dual FBG high-precision shape sensor successfully achieves high accuracy and reliability in shape reconstruction.


2021 ◽  
Vol 18 (185) ◽  
Author(s):  
Brett R. Aiello ◽  
Usama Bin Sikandar ◽  
Hajime Minoguchi ◽  
Burhanuddin Bhinderwala ◽  
Chris A. Hamilton ◽  
...  

Across insects, wing shape and size have undergone dramatic divergence even in closely related sister groups. However, we do not know how morphology changes in tandem with kinematics to support body weight within available power and how the specific force production patterns are linked to differences in behaviour. Hawkmoths and wild silkmoths are diverse sister families with divergent wing morphology. Using three-dimensional kinematics and quasi-steady aerodynamic modelling, we compare the aerodynamics and the contributions of wing shape, size and kinematics in 10 moth species. We find that wing movement also diverges between the clades and underlies two distinct strategies for flight. Hawkmoths use wing kinematics, especially high frequencies, to enhance force and wing morphologies that reduce power. Silkmoths use wing morphology to enhance force, and slow, high-amplitude wingstrokes to reduce power. Both strategies converge on similar aerodynamic power and can support similar body weight ranges. However, inter-clade within-wingstroke force profiles are quite different and linked to the hovering flight of hawkmoths and the bobbing flight of silkmoths. These two moth groups fly more like other, distantly related insects than they do each other, demonstrating the diversity of flapping flight evolution and a rich bioinspired design space for robotic flappers.


2021 ◽  
Vol 9 ◽  
Author(s):  
Micael Reis ◽  
Natalia Siomava ◽  
Ernst A. Wimmer ◽  
Nico Posnien

The ability of powered flight in insects facilitated their great evolutionary success allowing them to occupy various ecological niches. Beyond this primary task, wings are often involved in various premating behaviors, such as the generation of courtship songs and the initiation of mating in flight. These specific functions imply special adaptations of wing morphology, as well as sex-specific wing morphologies. Although wing morphology has been extensively studied in Drosophila melanogaster (Meigen, 1830), a comprehensive understanding of developmental plasticity and the impact of sex on wing size and shape plasticity is missing for other Diptera. Therefore, we raised flies of the three Diptera species Drosophila melanogaster, Ceratitis capitata (Wiedemann, 1824) and Musca domestica (Linnaeus, 1758) at different environmental conditions and applied geometric morphometrics to analyze wing shape. Our data showed extensive interspecific differences in wing shape, as well as a clear sexual wing shape dimorphism in all three species. We revealed an impact of different rearing temperatures on wing shape in all three species, which was mostly explained by plasticity in wing size in D. melanogaster. Rearing densities had significant effects on allometric wing shape in D. melanogaster, while no obvious effects were observed for the other two species. Additionally, we did not find evidence for sex-specific response to different rearing conditions in D. melanogaster and C. capitata, while a male-specific impact of different rearing conditions was observed on non-allometric wing shape in M. domestica. Overall, our data strongly suggests that many aspects of wing morphology underly species-specific adaptations and we discuss potential developmental and functional implications of our results.


2021 ◽  
Vol 13 (22) ◽  
pp. 12510
Author(s):  
Darija Lemic ◽  
Mario Bjeliš ◽  
Pave Ninčević ◽  
Ivana Pajač Živković ◽  
Luka Popović ◽  
...  

The hypothesis of this study was that different plant hosts of the medfly Ceratitis capitata may cause variability as a prerequisite for its invasiveness. The main objective was to determine population variability based on medfly wing shape in three favorable medfly host plants (peach, fig and mandarin) from different agroecological growing areas with different pest management practices, and to evaluate phenotypic plasticity as a basis for future expansion into new areas and new hosts. Using geometric morphometric methods across 14 specific landmarks on the medfly wings, 10 populations were tested from infested peach, fig and mandarin fruits, as well as laboratory-grown sterile populations. The studies led to the following main findings: (1) all of the medfly populations that were studied exhibited sexual dimorphism in wing shape; (2) the hosts in which the medfly develops influence wing shape and condition its variability; (3) there is significant variability between laboratory mass-reared sterile and wild individuals in male and female populations; (4) a high phenotypic plasticity of medfly populations was observed along the study sites. Even the low but clearly detected variability between different agroecological conditions and localized variability indicate genotypic stability and high phenotypic plasticity, which can be considered as a prerequisite for medfly invasiveness and dispersal to new areas.


2021 ◽  
Author(s):  
Norman MacLeod ◽  
Benjamin Price ◽  
Zachary Stevens

Abstract The phylogenetic ecology and wing ecomorphology of the Afro-Asian dragonfly genus Trithemis have been investigated previously. Curiously, results reported for the forewing and hindwing shape variation in the latter were, in some ways, at odds with expectations given the mapping of landscape and water-body preferences over the Trithemis cladogram. To confirm these results we conducted a wing-shape investigation of 27 Trithemis species that employed a robust statistical test for phylogenetic covariation, more comprehensive representation of Trithemis wing morphology and a wider range of morphometric data-analysis procedures. Contrary to results published previously, statistical comparisons of forewing and hindwing mean shapes with the Trithemis cladogram revealed no statistically significant pattern of phylogenetic covariation. Moreover, landmark-based and image-based geometric morphometric analysis results, as well as embedded image-contrast deep learning analysis results, all demonstrated that both wings exhibit substantial convergent wing-shape similarities among, and differences between, species that inhabit open and forested landscapes and species that hunt over temporary/standing or running water bodies. Geometric morphometric data and data-analysis methods yielded the worst performance in identifying wing shape distinctions between Trithemis habitat guilds and the direct analysis of wing images using an embedded, image-contrast, convolution (deep learning) neural network delivered the best performance. Bootstrap and jackknife tests confirmed that our results are not artifacts of overtrained discriminant systems or the “curse of dimensionality”. In addition to our conclusions pertaining to Trithemis ecomorphology, the discrepancy between the previous investigation’s results and ours appears to reflect decisions made with regard to the manner in which complex morphological structures are sampled and analyzed. Naturally, results and interpretations of patterns in morphometric data pertain only to the data collected, not necessarily to other aspects of the structures from which those data were collected. For samples of morphologically similar taxa, landmark-based sampling strategies may be effective provided a sufficient number of landmark points distributed across all structures of potential interest exist. However, in a large number of instances analysis of full digital images of the structures under consideration may prove to be a more robust and effective sampling strategy, especially when coupled with analysis via machine learning procedures.


Author(s):  
Waira Saravia Machida ◽  
Rosana Tidon ◽  
Julia Klaczko

Phenotypic plasticity has been described for morphological and life-history traits in many organisms. In Drosophila, temperature drives phenotypic change in several traits, but few neotropical species have been studied and whether the phenotypic variation associated with plasticity is adaptive remains unclear. Here, we studied the phenotypic response to temperature variation in the distant related neotropical species Drosophila mercatorum (Patterson and Wheeler, 1942) and Drosophila willistoni (Sturtevant, 1916). We evaluate if wing shape variation follows that observed in the neotropical species Drosophila cardini (Sturtevant, 1916): round wings at lower temperatures and narrower wings at higher temperatures. The variation in egg-adult development time and wing size, shape, and allometry was described using reaction norms and geometric morphometrics. In both species, development time and wing size decreased with increasing temperature and wing allometry showed that size explained ≈10% of the shape variation. Wing shape, however, exhibited contrasting responses. At higher temperatures, D. mercatorum developed slightly slender wings, following the pattern previously found for D. cardini, while D. willistoni developed plumper and shorter wings, supporting previous studies on Drosophila melanogaster (Meigen, 1830). We conclude that all traits studied here were influenced by temperature, and that wing shape seems also to be influenced by phylogeny.


Author(s):  
Iis Rohmawati ◽  
Hiroshi Arai ◽  
Hidemi Mutsuda ◽  
Takuji Nakashima ◽  
Rizal Mahmud

Experimental and numerical research have been performed to investigate the Wavy Leading Edge (WLE) effect on the rectangular wing. The WLE is inspired by humpback whale flipper morphology which is blunt and rounded in certain form pattern. This flipper shape plays an important role for its behaviour specially capturing their prey. This advantage could be applied to other systems such as fin stabilizers or wind turbines. Steady cases in various aspect ratios were conducted to find out the optimum effect of WLE with baseline NACA 0018 profile at Reynolds number 1.4 x 105. The chord length of the wing (c) was 125 mm. The WLE shape defined as wavelength (W) 8% of c and amplitude (d) is 5% of c. The aspect ratio (AR) variations were 1.6; 3.9; 5.1; 7.9 and 9.6.  A simple rectangular form of the wing was selected to analysis the WLE effect on the various ARs. The taper wing shape is applied to find out the WLE effect at the AR 7.9. three types of taper ratio (TR) are 0.1; 0.3 and 0.5. The results show that the WLE on the taper wing has better advantage to control the stall in steady case. Another impressive result was the WLE wing with AR 7.9 and TR 0.3 has the best lift coefficient and pressure distribution.Keywords: stall, wavy leading edge, steady case, rectangle wing, taper wing, aspect ratio. 


2021 ◽  
Vol 11 (1) ◽  
Author(s):  
David Outomuro ◽  
Maria J. Golab ◽  
Frank Johansson ◽  
Szymon Sniegula

AbstractLarge-scale latitudinal studies that include both north and south edge populations and address sex differences are needed to understand how selection has shaped trait variation. We quantified the variation of flight-related morphological traits (body size, wing size, ratio between wing size and body size, and wing shape) along the whole latitudinal distribution of the damselfly Lestes sponsa, spanning over 2700 km. We tested predictions of geographic variation in the flight-related traits as a signature of: (1) stronger natural selection to improve dispersal in males and females at edge populations; (2) stronger sexual selection to improve reproduction (fecundity in females and sexual behaviors in males) at edge populations. We found that body size and wing size showed a U-shaped latitudinal pattern, while wing ratio showed the inverse shape. However, wing shape varied very little along the latitudinal gradient. We also detected sex-differences in the latitudinal patterns of variation. We discuss how latitudinal differences in natural and sexual selection regimes can lead to the observed quadratic patterns of variation in body and wing morphology via direct or indirect selection. We also discuss the lack of latitudinal variation in wing shape, possibly due to aerodynamic constraints.


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