笛卡尔微分范畴的雅可比矩阵和梯度

J. Lemay
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引用次数: 0

摘要

笛卡尔微分范畴配备了一个微分组合子,它形式化了多变量微积分的方向导数。笛卡尔微分范畴提供了微分λ微积分的范畴语义,并且在因果计算、增量计算、博弈论、可微编程和机器学习中也有应用。最近有一种愿望是在笛卡尔微分范畴中提供雅可比矩阵和梯度的(无坐标的)表征。一个人的第一个尝试可能是考虑笛卡尔的微分范畴,它们是笛卡尔闭的,比如微分微积分的模型,然后取导数的咖喱。不幸的是,这种方法排除了笛卡尔微分范畴的许多重要例子,如实光滑函数的范畴。在本文中,我们引入了线性闭笛卡尔微分范畴,这是笛卡尔微分范畴具有线性映射的内域,双线性求值映射,以及在其第二参数上是线性映射的能力。因此,映射的雅可比矩阵被定义为其导数的curry。许多著名的笛卡尔微分范畴的例子是线性封闭的,特别是实光滑函数的范畴。我们还解释了当且仅当某个内直线上的线性幂等函数分裂时,一个笛卡尔闭微分范畴是线性闭的。要定义一个映射的梯度,必须能够定义雅可比矩阵的转置,这可以在笛卡尔逆微分范畴中完成。因此,我们将一个映射的梯度定义为它的逆导数的curry,并证明它等于它的雅可比矩阵的转置。我们还解释了一个线性封闭的笛卡尔逆微分范畴如何精确地是一个具有适当转置概念的线性封闭的笛卡尔微分范畴。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Jacobians and Gradients for Cartesian Differential Categories
Cartesian differential categories come equipped with a differential combinator that formalizes the directional derivative from multivariable calculus. Cartesian differential categories provide a categorical semantics of the differential lambda-calculus and have also found applications in causal computation, incremental computation, game theory, differentiable programming, and machine learning. There has recently been a desire to provide a (coordinate-free) characterization of Jacobians and gradients in Cartesian differential categories. One's first attempt might be to consider Cartesian differential categories which are Cartesian closed, such as models of the differential lambda-calculus, and then take the curry of the derivative. Unfortunately, this approach excludes numerous important examples of Cartesian differential categories such as the category of real smooth functions. In this paper, we introduce linearly closed Cartesian differential categories, which are Cartesian differential categories that have an internal hom of linear maps, a bilinear evaluation map, and the ability to curry maps which are linear in their second argument. As such, the Jacobian of a map is defined as the curry of its derivative. Many well-known examples of Cartesian differential categories are linearly closed, such as, in particular, the category of real smooth functions. We also explain how a Cartesian closed differential category is linearly closed if and only if a certain linear idempotent on the internal hom splits. To define the gradient of a map, one must be able to define the transpose of the Jacobian, which can be done in a Cartesian reverse differential category. Thus, we define the gradient of a map to be the curry of its reverse derivative and show this equals the transpose of its Jacobian. We also explain how a linearly closed Cartesian reverse differential category is precisely a linearly closed Cartesian differential category with an appropriate notion of transpose.
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