Modeling and simulation of spider’s walking

Mojdehi, A. Rezaei; Alitavoli, M.; Darvizeh, A.; Rajabi, Hamed; Larijani, Hadi

doi:10.2495/dne-v6-n2-83-96

Cited by 2 publications

(2 citation statements)

References 32 publications

(19 reference statements)

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“…There are works devoted to the study of individual limbs of a spider-robot. In [6] the adhesion of the limb to the surface is studied; in [7], [8], [9] and [10] they model a limb based on data obtained from living spiders; in [11], researchers use a spring-loaded inverted pendulum model as a limb mechanism, which allowed them to imitate walking, 43 running and jumping; and in [12] the results of the development of the limb of the arachnid monkey are given. The articles [13] and [14] provide solutions to the inverse kinematic problem.…”

Section: Designing a Spider-robotmentioning

confidence: 99%

Mathematical Model of a Robot-spider for Group Control Synthesis: Derivation and Validation

Kravchenko,

Efremov,

Zhilenkov

et al. 2023

Journal of Robotics and Control

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A six-legged spider robot is a complex object from the point of view of the problem of synthesizing a system for controlling its movement. To synthesize an advanced control system for such a robot, which must solve non-trivial problems of overcoming obstacles, functioning under conditions of external disturbances, etc., we first solve the problem of synthesizing an information model of the object, on the basis of which its control system will subsequently be built.The paper compares two methods for synthesizing the information model of a six-legged spider-robot. In the first method, an information model is automatically synthesized from a CAD model of a spider-robot in a MATLAB-based graphical programming environment Simulink. In the second method, the information model is synthesized in the environment of dynamic modeling of technical systems SimInTech on the basis of a system of differential equations in the Cauchy form. Control loops and external influences are added to the information models synthesized in each of the modeling environments. The study showed that each of the resulting models has both its own individual advantages and disadvantages. They are mainly related to taking into account the mutual influence of various blocks of models on each other. It is shown that, in the end, the two models complement each other and make it possible to obtain an advanced basis for further synthesis of the motion control system.The results obtained in this work make it possible to use information models as a basis for the development of a control system for a physical model of a six-legged spider-robot, printed on a 3D printer and assembled on the basis of the Arduino hardware platform.

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Section: Designing a Spider-robotmentioning

confidence: 99%

Mathematical Model of a Robot-spider for Group Control Synthesis: Derivation and Validation

Kravchenko,

Efremov,

Zhilenkov

et al. 2023

Journal of Robotics and Control

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“…Therefore, most of such robots tend to have an even number of limbs, four [6], [16], six [22]- [25] or eight [3], [5], [26]- [30]. In addition to the number of limbs, researchers are trying to adopt some features of the movement of spiders, for example, the ability to jump [22], [31] and run [22], move over rough terrain [24], [26], [32], [33], grip [2], [9], [34], and flip from the back [35]. Part of the research is devoted to finding optimal algorithms for moving limbs [29], finding stable support points [36]- [39] or considering rolling as another way to move limbs [40].…”

Section: Introductionmentioning

confidence: 99%

Comparison of Spider-Robot Information Models

Kravchenko,

Efremov,

Zhilenkov

et al. 2023

Journal of Robotics and Control

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The paper deduces a mathematical model of a spider-robot with six three-link limbs. Many limbs with a multi-link structure greatly complicate the process of synthesizing a model, since in total the robot has twenty-four degrees of freedom, i.e., three coordinates of the center of mass of the body in space, three angles of rotation of the body relative to its center of mass and three degrees of freedom for each limb, to describe the position of the links. The derived mathematical model is based on the Lagrange equations with a further transformation of the equations to the Cauchy normal form in a matrix form. To test the resulting model in a SimInTech environment, an information model is synthesized and two simple experiments ar carried out to simulate the behavior of real spiders: moving forward in a straight line and turning in place at a given angle. The experimental results demonstrate that the synthesized information model can well cope with the tasks and the mathematical model underlying it can be used for further research.

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Modeling and simulation of spider’s walking

Cited by 2 publications

References 32 publications

Mathematical Model of a Robot-spider for Group Control Synthesis: Derivation and Validation

Mathematical Model of a Robot-spider for Group Control Synthesis: Derivation and Validation

Comparison of Spider-Robot Information Models

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