Difference between revisions of "Virtual laboratory"

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[[ru:Виртуальная лаборатория]]
 
[[ru:Виртуальная лаборатория]]
 
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<center><h1>Welcome to Virtual laboratory page!</h1></center>
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<center><h1>Welcome to the Virtual laboratory page!</h1></center>
  
Here you can see projects, that allow you to conduct experiments online in an interactive mode. You can investigate all possible systems: mathematical, mechanical, physical, biological, etc. Also, you can learn online programming and visualization.
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Here you can see computer experiments in interactive online format. Various systems can be investigated: mathematical, mechanical, physical, biological, etc. Also, you can learn online programming and visualization. More experiments are available on the Russian page (see the link at the left panel).
 
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<div style="font-size:135%; text-align:center; font-weight:bold">[[Игра "Жизнь"]]</div>
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<div style="font-size:135%; text-align:center; font-weight:bold">[[:ru:Игра "Жизнь" | Conway's Game of Life]]</div>
 
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Программа, представляющая из себя классическую игру [http://ru.wikipedia.org/wiki/Жизнь_(игра) "Жизнь"] Джона Конвея с возможностью рисовать курсором клетки на поле.
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The program, representing a classic [https://en.wikipedia.org/wiki/Conway's_Game_of_Life "Conway's Game of Life"]. The cells can be drawn on the field by cursor.
 
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<div style="font-size:135%; text-align:center; font-weight:bold">[[Моделирование Солнечной системы|Модель Солнечной системы]]</div>
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<div style="font-size:135%; text-align:center; font-weight:bold">[[:ru:Моделирование Солнечной системы|Solar System model]]</div>
 
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Данная модель демонстрирует реальное соотношение периодов обращения планет.
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This model demonstrates the real attitude of the orbital periods of the planets. The radiuses of the planet orbits, as well as the sizes of the planets and the Sun are shown in a logarithmic scale.
Радиусы орбит планет, а также размеры планет и Солнца показаны в логарифмическом масштабе.
 
 
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<div style="font-size:135%; text-align:center; font-weight:bold">[[Движение материальной точки в центральном поле]]</div>
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<div style="font-size:135%; text-align:center; font-weight:bold">[[:ru:Движение материальной точки в центральном поле | Dynamics of a particle in a central field]]</div>
 
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Интерактивное приложение позволяет изучать траектории материальной точки в центральном степенном поле притяжения.
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The application allows you to study a particle trajectory in a central power-law potential field.
 
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<div style="font-size:135%; text-align:center; font-weight:bold">[[Динамика взаимодействующих частиц]]</div>
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<div style="font-size:135%; text-align:center; font-weight:bold">[[:ru:Динамика взаимодействующих частиц | Dynamics of interacting particles]]</div>
 
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Программа моделирует динамику взаимодуйствующих частиц. Каждая частица представляет из себя вязкоупругий шар.
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The program simulates dynamics of interacting particles. Each particle represents a viscoelastic sphere.
 
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<div style="font-size:135%; text-align:center; font-weight:bold">[[Динамика одномерного кристалла|Цепь]]</div>
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<div style="font-size:135%; text-align:center; font-weight:bold">[[:ru:Динамика одномерного кристалла|Chain]]</div>
 
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Программа, моделирующая динамику одномерного кристалла.
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The program simulates dynamics of a 1D harmonic crystal.
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See also [[Heat transfer in a 1D harmonic crystal]].
 
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<div style="font-size:135%; text-align:center; font-weight:bold">[[Моделирование структуры кристаллических решеток]]</div>
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<div style="font-size:135%; text-align:center; font-weight:bold">[[:ru:Моделирование структуры кристаллических решеток | Periodic vacancies in a crystal lattice]]</div>
 
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Программа, моделирующая различные структуры кристаллических решеток.
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The program demontrates different crystal lattice structures.
 
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<center><h1> Some other virtual stands arranged by topic </h1></center>
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== Mechanics ==
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*[[Analysis of a simple harmonic oscillator]]
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*[[Interactive harmonic oscillator model ]]
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*[[Analysis of a simple nonlinear oscillating system]]
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== Physics ==
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* [[Energy fluctuations in one-dimensional crystal]]
 
* [[Heat transfer in a 1D harmonic crystal]]
 
* [[Heat transfer in a 1D harmonic crystal]]
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* [[Nosé–Hoover thermostat]]
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* [[Displacement variance in one-dimensional crystal]]
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== Links ==
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* [[Main_Page | Department "Theoretical Mechanics"]]

Latest revision as of 02:09, 4 June 2016


Welcome to the Virtual laboratory page!


Here you can see computer experiments in interactive online format. Various systems can be investigated: mathematical, mechanical, physical, biological, etc. Also, you can learn online programming and visualization. More experiments are available on the Russian page (see the link at the left panel).

Cellular automaton

The program, representing a classic "Conway's Game of Life". The cells can be drawn on the field by cursor.

Solar System

This model demonstrates the real attitude of the orbital periods of the planets. The radiuses of the planet orbits, as well as the sizes of the planets and the Sun are shown in a logarithmic scale.

The application allows you to study a particle trajectory in a central power-law potential field.


 Balls

The program simulates dynamics of interacting particles. Each particle represents a viscoelastic sphere.

Chain

The program simulates dynamics of a 1D harmonic crystal. See also Heat transfer in a 1D harmonic crystal.

Lattice

The program demontrates different crystal lattice structures.


Some other virtual stands arranged by topic


Mechanics[edit]

Physics[edit]

Links[edit]