Solving one dimensional time-space fractional vibration string equation

Limbless crawling is a fundamental form of biological locomotion adopted by a wide variety of species, including the amoeba, earthworm and snake. An interesting question from a biomechanics perspective is how limbless crawlers control their flexible bodies in order to realize directional migration. In this paper, we discuss the simple but instructive problem of peristalsis-like locomotion driven by elongation–contraction waves that propagate along the body axis, a process frequently observed in slender species such as the earthworm. We show that the basic equation describing this type of locomotion is a linear, one-dimensional diffusion equation with a time–space-dependent diffusion coefficient and a source term, both of which express the biological action that drives the locomotion. A perturbation analysis of the equation reveals that adequate control of friction with the substrate on which locomotion occurs is indispensable in order to translate the internal motion (propagation of the elongation–contraction wave) into directional migration. Both the locomotion speed and its direction (relative to the wave propagation) can be changed by the control of friction. The biological relevance of this mechanism is discussed.

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Numerical Solution and Application of Time-Space Fractional Governing Equations of One-Dimensional Unsteady Open Channel Flow Process

10.5194/hess-2016-364 ◽

2016 ◽

Cited By ~ 1

Author(s):

Ali Ercan ◽

M. Levent Kavvas

Keyword(s):

Channel Flow ◽

Open Channel ◽

Open Channel Flow ◽

Transport Processes ◽

Governing Equations ◽

Flow Process ◽

One Dimensional ◽

Time Space ◽

Flow Processes ◽

Saint Venant Equations

Abstract. Although fractional integration and differentiation have found many applications in various fields of science, such as physics, finance, bioengineering, continuum mechanics and hydrology, their engineering applications, especially in the field of fluid flow processes, are rather limited. In this study, a finite difference numerical approach is proposed to solve the time-space fractional governing equations of one-dimensional unsteady/non-uniform open channel flow process. By numerical simulations, results of the proposed fractional governing equations of the open channel flow process were compared with those of the standard Saint Venant equations. Numerical simulations showed that flow discharge and water depth can exhibit heavier tails in downstream locations as space and time fractional derivative powers decrease from 1. The fractional governing equations under consideration are generalizations of the well-known Saint Venant equations, which are written in the integer differentiation framework. The new governing equations in the fractional order differentiation framework have the capability of modeling nonlocal flow processes both in time and in space by taking the global correlations into consideration. Furthermore, the generalized flow process may shed light into understanding the theory of the anomalous transport processes and observed heavy tailed distributions of particle displacements in transport processes.

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Time-space fractional governing equations of one-dimensional unsteady open channel flow process: Numerical solution and exploration

Hydrological Processes ◽

10.1002/hyp.11240 ◽

2017 ◽

Vol 31 (16) ◽

pp. 2961-2971 ◽

Cited By ~ 3

Author(s):

Ali Ercan ◽

M. Levent Kavvas

Keyword(s):

Numerical Solution ◽

Channel Flow ◽

Open Channel ◽

Open Channel Flow ◽

Governing Equations ◽

Flow Process ◽

One Dimensional ◽

Time Space

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Computer Simulation of Torsional Waves in a Single Gear Transmission

6th International Power Transmission and Gearing Conference: Advancing Power Transmission Into the 21st Century ◽

10.1115/detc1992-0030 ◽

1992 ◽

Author(s):

A. Mioduchowski ◽

W. Nadolski

Keyword(s):

Computer Simulation ◽

Elastic Waves ◽

Continuous Model ◽

Gear Transmission ◽

Dynamical Analysis ◽

One Dimensional ◽

Time Space ◽

Torsional Waves

Abstract The theory of one dimensional torsional elastic waves is used for the dynamical analysis of a discrete-continuous model of a single gear transmission. The method allows for the calculation of results either as functions of time or as functions of location. These results can be put together into a 3D time-space display offering an interesting tool in simulation of torsional waves in a single gear transmission.

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Unified approach to the impulse response and green function in the circuit and field theory, part I: one–dimensional case

Journal of Electrical Engineering ◽

10.2478/v10187-012-0040-8 ◽

2012 ◽

Vol 63 (5) ◽

pp. 273-280 ◽

Cited By ~ 1

Author(s):

L’Ubomír Šumichrast

Keyword(s):

Impulse Response ◽

Transmission Lines ◽

Delta Function ◽

Step Function ◽

Subsequent Paper ◽

Unified Approach ◽

One Dimensional ◽

Dirac Delta ◽

Time Space ◽

Heaviside Unit Step Function

In the circuit theory the concept of the impulse response of a linear system due to its excitation by the Dirac delta function ƍ(t) together with the convolution principle is widely used and accepted. The rigorous theory of symbolic functions, sometimes called distributions, where also the delta function belongs, is rather abstract and requires subtle mathematical tools [1], [2], [3], [4]. Nevertheless, the most people intuitively well understand the delta function as a derivative of the (Heaviside) unit step function 1(t) without too much mathematical rigor. The concept of the impulse response of linear systems is here approached in a unified manner and generalized to the time-space phenomena in one dimension (transmission lines), as well as in a subsequent paper [5] to the phenomena in more dimensions (static and dynamic electromagnetic fields).

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