The centers of gravity and dynamic types of body shape of terrestrial invertebrates

被引:0
|
作者
V. P. Pekin
B. M. Chichkov
机构
[1] Chelyabinsk State University,Il’men’ State Reserve, Ural Division
[2] Russian Academy of Sciences,undefined
来源
Russian Journal of Ecology | 2008年 / 39卷
关键词
invertebrates; center of gravity; geometrical center of projections; dynamic type of body shape; dynamic morphology; life forms; structural and functional organization of communities;
D O I
暂无
中图分类号
学科分类号
摘要
In the framework of dynamic morphology theory, the centers of gravity and geometric centers of projections have been determined for the bodies of more than 182 forms of invertebrates, and these data have been used to distinguish four types of dynamic body shapes. It has been demonstrated that specific dynamic types of body shape are characteristic of individual taxa. In addition, there are a group of “transformers,” which may assume any dynamic type of shape, and a group of invertebrates with one predominant dynamic type.
引用
收藏
页码:48 / 55
页数:7
相关论文
共 50 条
  • [21] Temperature effect on the temporal dynamic of terrestrial invertebrates in technosols formed after reclamation at a post-mining site in Ukrainian steppe drylands
    Pakhomov, O. Y.
    Kunakh, O. M.
    Babchenko, A. V.
    Fedushko, M. P.
    Demchuk, N. I.
    Bezuhla, L. S.
    Tkachenko, O. S.
    BIOSYSTEMS DIVERSITY, 2019, 27 (04): : 322 - 328
  • [22] New types of experimental data shape the use of enzyme kinetics for dynamic network modeling
    Tummler, Katja
    Lubitz, Timo
    Schelker, Max
    Klipp, Edda
    FEBS JOURNAL, 2014, 281 (02) : 549 - 571
  • [23] Modelling of Dynamic On-Body Channels Using Different Types of Wearable Antennas
    Paraskevopoulos, A.
    Alexandridis, A.
    Zervos, T.
    Michalopoulou, A.
    Lazarakis, F.
    Vardaxoglou, J. C.
    2014 8TH EUROPEAN CONFERENCE ON ANTENNAS AND PROPAGATION (EUCAP), 2014, : 852 - 856
  • [24] Zonal Winds of Uranus and Neptune: Gravitational Harmonics, Dynamic Self-gravity, Shape, and Rotation
    Soyuer, Deniz
    Neuenschwander, Benno
    Helled, Ravit
    ASTRONOMICAL JOURNAL, 2023, 165 (01):
  • [25] The role of dynamic shape cues in the recognition of emotion from naturalistic body motion
    Ikeda, Erika
    Destler, Nathan
    Feldman, Jacob
    ATTENTION PERCEPTION & PSYCHOPHYSICS, 2025, 87 (02) : 604 - 618
  • [26] Computation of shape and drag of a deforming elastic body under fluid dynamic force
    Hashimoto, Tomohisa
    Morinishi, Koji
    Satofuka, Nobuyuki
    COMPUTERS & FLUIDS, 2009, 38 (07) : 1361 - 1368
  • [27] Effects of spawning Pacific salmon on terrestrial invertebrates: Insects near spawning habitat are isotopically enriched with nitrogen-15 but display no differences in body size
    Rammell, Nicola F.
    Dennert, Allison M.
    Ernst, Christopher M.
    Reynolds, John D.
    ECOLOGY AND EVOLUTION, 2021, 11 (18): : 12728 - 12738
  • [28] Effects of the performance parameters of a wheelchair on the changes in the position of the centre of gravity of the human body in dynamic condition
    Wieczorek, Bartosz
    Kukla, Mateusz
    PLOS ONE, 2019, 14 (12):
  • [29] MASSES, CENTERS-OF-GRAVITY, AND MOMENTS-OF-INERTIA OF BODY SEGMENTS OF RHESUS-MONKEY (MACACA-MULATTA)
    VILENSKY, JA
    AMERICAN JOURNAL OF PHYSICAL ANTHROPOLOGY, 1979, 50 (01) : 57 - 65
  • [30] Evolution of morphology in Western Palaearctic salamanders: do climate and reproductive mode drive body size and shape in terrestrial salamanders?
    Amat, Felix
    SALAMANDRA, 2021, 57 (01): : 44 - 52
12345