Notes for AKT-140110/0:35:38: Difference between revisions
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'''Lagrangian Mechanics''' is a tool used in studying motions in Classical Mechanics and it was introduced by Joseph-Louis Lagrange in 1788. An important concept in Lagragian Mechanics is that the equations of motion of Classical Mechanics can be based on a variational principle, namely, that along a path describing classical motion the '''action integral''' assumes a minimal value (Hamiltonian Principle of Least Action) |
'''Lagrangian Mechanics''' is a tool used in studying motions in Classical Mechanics and it was introduced by Joseph-Louis Lagrange in 1788. An important concept in Lagragian Mechanics is that the equations of motion of Classical Mechanics can be based on a variational principle, namely, that along a path describing classical motion the '''action integral''' assumes a minimal value (Hamiltonian Principle of Least Action) |
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The action integral is given by <math>S[x(t)] = \int^{t_1}_{t_0} dt \mathcal{L}(x(t), |
The action integral is given by <math>S[x(t)] = \int^{t_1}_{t_0} dt \mathcal{L}(x(t),,t)</math>, where <math>\mathcal{L}(x(t),\.{x(t)},t) = \frac12 \.{x(t)}^2-U(x(t))/math> is called the Lagrangian. |
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Revision as of 15:52, 25 May 2018
Lagrangian Mechanics is a tool used in studying motions in Classical Mechanics and it was introduced by Joseph-Louis Lagrange in 1788. An important concept in Lagragian Mechanics is that the equations of motion of Classical Mechanics can be based on a variational principle, namely, that along a path describing classical motion the action integral assumes a minimal value (Hamiltonian Principle of Least Action)
The action integral is given by , where <math>\mathcal{L}(x(t),\.{x(t)},t) = \frac12 \.{x(t)}^2-U(x(t))/math> is called the Lagrangian.
![{\displaystyle S[x(t)]=\int _{t_{0}}^{t_{1}}dt{\mathcal {L}}(x(t),,t)}](https://wikimedia.org/api/rest_v1/media/math/render/svg/4ecf2c9573191568c18e8c9f4e49a40cfd573403)
