Nullcline

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In mathematical analysis, nullclines, sometimes called zero-growth isoclines, are encountered in a system of ordinary differential equations

$x_{1}'=f_{1}(x_{1},\ldots ,x_{n})$

$x_{2}'=f_{2}(x_{1},\ldots ,x_{n})$

$\vdots$

$x_{n}'=f_{n}(x_{1},\ldots ,x_{n})$

where $x'$ here represents a derivative of $x$ with respect to another parameter, such as time $t$ . The $j$ 'th nullcline is the geometric shape for which $x_{j}'=0$ . The fixed points of the system are located where all of the nullclines intersect. In a two-dimensional linear system, the nullclines can be represented by two lines on a two-dimensional plot; in a general two-dimensional system they are arbitrary curves.

History

The definition, though with the name ’directivity curve’, was used in a 1967 article by Endre Simonyi¹. This article also defined 'directivity vector' as ${\mathbf {w}}={\mathrm {sign}}(P){\mathbf {i}}+{\mathrm {sign}}(Q){\mathbf {j}}$ , where P and Q are the dx/dt and dy/dt differential equations, and i and j are the x and y direction unit vectors.

Simonyi developed a new stability test method from these new definitions, and with it he studied differential equations. This method, beyond the usual stability examinations, provided semiquantative results.

References

1.E. Simonyi: The Dynamics of the Polymerization Processes, Periodica Polytechnica Electrical Engineering – Elektrotechnik, Polytechnical University Budapest, 1967

2. E. Simonyi – M. Kaszás: Method for the Dynamic Analysis of Nonlinear Systems, Periodica Polytechnica Chemical Engineering – Chemisches Ingenieurwesen, Polytechnical University Budapest, 1969

External links

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