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In mathematics, a non-autonomous system of ordinary differential equations is defined to be a dynamic equation on a smooth fiber bundle ${\displaystyle Q\to \mathbb{ℝ}}$ over ${\displaystyle \mathbb{ℝ}}$. For instance, this is the case of non-relativistic non-autonomous mechanics, but not relativistic mechanics. To describe relativistic mechanics, one should consider a system of ordinary differential equations on a smooth manifold ${\displaystyle Q}$ whose fibration over ${\displaystyle \mathbb{ℝ}}$ is not fixed. Such a system admits transformations of a coordinate ${\displaystyle t}$ on ${\displaystyle \mathbb{ℝ}}$ depending on other coordinates on ${\displaystyle Q}$. Therefore, it is called the relativistic system. In particular, Special Relativity on the Minkowski space ${\displaystyle Q={\mathbb{ℝ}}^4}$ is of this type.

Since a configuration space ${\displaystyle Q}$ of a relativistic system has no preferable fibration over ${\displaystyle \mathbb{ℝ}}$, a velocity space of relativistic system is a first order jet manifold ${\displaystyle J_1^{1}Q}$ of one-dimensional submanifolds of ${\displaystyle Q}$. The notion of jets of submanifolds generalizes that of jets of sections of fiber bundles which are utilized in covariant classical field theory and non-autonomous mechanics. A first order jet bundle ${\displaystyle J_1^{1}Q\to Q}$ is projective and, following the terminology of Special Relativity, one can think of its fibers as being spaces of the absolute velocities of a relativistic system. Given coordinates ${\displaystyle (q^0,q^i)}$ on ${\displaystyle Q}$, a first order jet manifold ${\displaystyle J_1^{1}Q}$ is provided with the adapted coordinates ${\displaystyle (q^0,q^i,q_0^i)}$ possessing transition functions

${\displaystyle q{\text{'}}^0=q{\text{'}}^0(q^0,q^k),q{\text{'}}^i=q{\text{'}}^i(q^0,q^k),{q^{\prime }}_0^i=(\frac{\partial q{\text{'}}^i}{\partial q^j}{q}_0^j+\frac{\partial q{\text{'}}^i}{\partial q^0}){(\frac{\partial q{\text{'}}^0}{\partial q^j}{q}_0^j+\frac{\partial q{\text{'}}^0}{\partial q^0})}^{-1}.}$

The relativistic velocities of a relativistic system are represented by elements of a fibre bundle ${\displaystyle \mathbb{ℝ}\times TQ}$, coordinated by ${\displaystyle (\tau ,q^{\lambda },a_{\tau }^{\lambda })}$, where ${\displaystyle TQ}$ is the tangent bundle of ${\displaystyle Q}$. Then a generic equation of motion of a relativistic system in terms of relativistic velocities reads

${\displaystyle (\frac{{\partial }_{\lambda }{G}_{\mu {\alpha }_2\dots {\alpha }_{2N}}}{2N}-{\partial }_{\mu }{G}_{\lambda {\alpha }_2\dots {\alpha }_{2N}})q_{\tau }^{\mu }{q}_{\tau }^{{\alpha }_2}\cdots q_{\tau }^{{\alpha }_{2N}}-(2N-1)G_{\lambda \mu {\alpha }_3\dots {\alpha }_{2N}}{q}_{\tau \tau }^{\mu }{q}_{\tau }^{{\alpha }_3}\cdots q_{\tau }^{{\alpha }_{2N}}+F_{\lambda \mu }{q}_{\tau }^{\mu }=0,}$

${\displaystyle G_{{\alpha }_1\dots {\alpha }_{2N}}{q}_{\tau }^{{\alpha }_1}\cdots q_{\tau }^{{\alpha }_{2N}}=1.}$

For instance, if ${\displaystyle Q}$ is the Minkowski space with a Minkowski metric ${\displaystyle G_{\mu \nu }}$, this is an equation of a relativistic charge in the presence of an electromagnetic field.

References

• Krasil'shchik, I. S., Vinogradov, A. M., [et al.], "Symmetries and conservation laws for differential equations of mathematical physics", Amer. Math. Soc., Providence, RI, 1999, ISBN 0-8218-0958-X.
• Giachetta, G., Mangiarotti, L., Sardanashvily, G., Geometric Formulation of Classical and Quantum Mechanics (World Scientific, 2010) ISBN 981-4313-72-6 (arXiv: 1005.1212).

See also

• Non-autonomous system (mathematics)
• Non-autonomous mechanics
• Relativistic mechanics
• Special relativity