衍射不变性与广义相对论

Max Heitmann
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引用次数: 0

摘要

衍射不变性通常被认为是广义相对论(GR)的标志。但仔细分析就会发现,这并不是广义相对论与众不同之处。衍射不变性的概念有两种定义:根据第一种定义(衍射不变性$_1$),广义相对论和所有其他经典时空理论都是衍射不变的;而根据第二种定义(衍射不变性$_2$),广义相对论和所有其他经典时空理论都不是衍射不变的。关于这个问题的混乱可以追溯到两个方面。首先,《全球定位系统》有时被误认为体现了 "相对性一般原理",该原理断言所有运动状态都具有相对性,并由此推导出《全球定位系统》必须是差分不变的_2$。但是,GR 并没有体现这样的原则,而且很容易看出它违反了差分不变性$_2$。其次,GR 在时空理论中是独一无二的,因为它需要用广义协变来表述,而其他经典时空理论通常是根据一类首选的全局坐标系来表述的,在这类坐标系中,它们的动力学方程可以简化。这使得 GR 的差分不变性(在差分不变性$_1$ 的意义上)显而易见,而在其他时空理论中,它是潜在的--至少在它们熟悉的表述中是这样。我把这种差异追溯到这样一个事实,即时空结构在 GR 模型中是不均匀的,而在不同模型中是可变的。我为时空理论何时拥有不变的时空结构提供了一个形式化的标准,并利用这个标准证明,当且仅当一个理论拥有不变的时空结构时,它才拥有一类可适用于不同模型的优选坐标系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Diffeomorphism Invariance and General Relativity
Diffeomorphism invariance is often considered to be a hallmark of the theory of general relativity (GR). But closer analysis reveals that this cannot be what makes GR distinctive. The concept of diffeomorphism invariance can be defined in two ways: under the first definition (diff-invariance$_1$), both GR and all other classical spacetime theories turn out to be diffeomorphism invariant, while under the second (diff-invariance$_2$), neither do. Confusion about the matter can be traced to two sources. First, GR is sometimes erroneously thought to embody a "general principle of relativity," which asserts the relativity of all states of motion, and from which it would follow that GR must be diff-invariant$_2$. But GR embodies no such principle, and is easily seen to violate diff-invariance$_2$. Second, GR is unique among spacetime theories in requiring a general-covariant formulation, whereas other classical spacetime theories are typically formulated with respect to a preferred class of global coordinate systems in which their dynamical equations simplify. This makes GR's diffeomorphism invariance (in the sense of diff-invariance$_1$) manifest, while in other spacetime theories it lies latent -- at least in their familiar formulations. I trace this difference back to the fact that the spacetime structure is inhomogeneous within the models of GR, and mutable across its models. I offer a formal criterion for when a spacetime theory possesses immutable spacetime structure, and using this criterion I prove that a theory possesses a preferred class of coordinate systems applicable across its models if and only if it possesses immutable spacetime structure.
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