Product rule for partial differentiation

Statement for two functions

The derivatives used here are partial derivatives.

Version type	Statement
specific point, named functions	Suppose $f, g$ are both functions of variables $x, y$ . Suppose $(x_{0}, y_{0})$ is a point in the domain of both $f$ and $g$ . Suppose the partial derivatives $f_{x} (x_{0}, y_{0})$ and $g_{x} (x_{0}, y_{0})$ both exist. Let $f g$ denote the product of the functions. Then, we have: $(f g)_{x} (x_{0}, y_{0}) = f_{x} (x_{0}, y_{0}) g (x_{0}, y_{0}) + f (x_{0}, y_{0}) g_{x} (x_{0}, y_{0})$ Suppose the partial derivatives $f_{y} (x_{0}, y_{0})$ and $g_{y} (x_{0}, y_{0})$ both exist. Then, we have: $(f g)_{y} (x_{0}, y_{0}) = f_{y} (x_{0}, y_{0}) g (x_{0}, y_{0}) + f (x_{0}, y_{0}) g_{y} (x_{0}, y_{0})$
generic point, named functions	Suppose $f, g$ are both functions of variables $x, y$ . $(f g)_{x} (x, y) = f_{x} (x, y) g (x, y) + f (x, y) g_{x} (x, y)$ $(f g)_{y} (x, y) = f_{y} (x, y) g (x, y) + f (x, y) g_{y} (x, y)$ These hold wherever the right side expressions make sense (see concept of equality conditional to existence of one side).
generic point, named functions, point-free notation	Suppose $f, g$ are both functions of variables $x, y$ . $(f g)_{x} = f_{x} g + f g_{x}$ $(f g)_{y} = f_{y} g + f g_{y}$ These hold wherever the right side expressions make sense (see concept of equality conditional to existence of one side).

Version type	Statement
specific point, named functions	Suppose $f, g$ are both functions of variables $x_{1}, x_{2}, \dots, x_{n}$ . Suppose $(a_{1}, a_{2}, \dots, a_{n})$ is a point in the domain of both $f$ and $g$ . Fix a number $i$ in ${1, 2, 3, \dots, n}$ . Suppose the partial derivatives $f_{x_{i}} (a_{1}, a_{2}, \dots, a_{n})$ and $g_{x_{i}} (a_{1}, a_{2}, \dots, a_{n})$ both exist. Let $f g$ denote the product of the functions. Then, we have: $(f g)_{x_{i}} (a_{1}, a_{2}, \dots, a_{n}) = f_{x_{i}} (a_{1}, a_{2}, \dots, a_{n}) g (a_{1}, a_{2}, \dots, a_{n}) + f (a_{1}, a_{2}, \dots, a_{n}) g_{x_{i}} (a_{1}, a_{2}, \dots, a_{n})$
generic point, named functions	Suppose $f, g$ are both functions of variables $x_{1},_{2}, \dots, x_{n}$ . Then, for any fixed $i$ in ${1, 2, 3, \dots, n}$ : $(f g)_{x_{i}} (x_{1}, x_{2}, \dots, x_{n}) = f_{x_{i}} (x_{1}, x_{2}, \dots, x_{n}) g (x_{1}, x_{2}, \dots, x_{n}) + f (x_{1}, x_{2}, \dots, x_{n}) g_{x_{i}} (x_{1}, x_{2}, \dots, x_{n})$ These hold wherever the right side expressions make sense (see concept of equality conditional to existence of one side).
generic point, named functions, point-free notation	Suppose $f, g$ are both functions of variables $x, y$ . Then, for any fixed $i$ in ${1, 2, 3, \dots, n}$ : $(f g)_{x_{i}} = f_{x_{i}} g + f g_{x_{i}}$ These hold wherever the right side expressions make sense (see concept of equality conditional to existence of one side).

Version type	Statement
specific point, named functions	Suppose $f, g$ are both real-valued functions of a vector variable $\bar{x}$ . Suppose $\bar{u}$ is a unit vector. Suppose $\bar{x_{0}}$ is a point in the domain of both functions. Then, we have the following product rule for directional derivatives: $\nabla_{\bar{u}} (f g) (\bar{x_{0}}) = \nabla_{\bar{u}} (f) (\bar{x_{0}}) g (\bar{x_{0}}) + f (\bar{x_{0}}) \nabla_{\bar{u}} (g) (\bar{x_{0}})$
generic point, named functions	Suppose $f, g$ are both real-valued functions of a vector variable $\bar{x}$ . Suppose $\bar{u}$ is a unit vector. Then, we have the following product rule for directional derivatives wherever the right side expression makes sense (see concept of equality conditional to existence of one side): $\nabla_{\bar{u}} (f g) (\bar{x}) = \nabla_{\bar{u}} (f) (\bar{x}) g (\bar{x}) + f (\bar{x}) \nabla_{\bar{u}} (g) (\bar{x})$ .
generic point, named functions, point-free notation	Suppose $f, g$ are both real-valued functions of a vector variable $\bar{x}$ . Suppose $\bar{u}$ is a unit vector. Then, we have the following product rule for directional derivatives wherever the right side expression makes sense (see concept of equality conditional to existence of one side): $\nabla_{\bar{u}} (f g) = \nabla_{\bar{u}} (f) g + f \nabla_{\bar{u}} (g)$ .

Version type	Statement
specific point, named functions	Suppose $f, g$ are both real-valued functions of a vector variable $\bar{x}$ . Suppose $\bar{x_{0}}$ is a point in the domain of both functions. Then, we have the following product rule for gradient vectors: $\nabla (f g) (\bar{x_{0}}) = g (\bar{x_{0}}) \nabla (f) (\bar{x_{0}}) + f (\bar{x_{0}}) \nabla (g) (\bar{x_{0}})$ . Note that the products on the right side are scalar-vector multiplications.
generic point, named functions	Suppose $f, g$ are both real-valued functions of a vector variable $\bar{x}$ . Then, we have the following product rule for gradient vectors wherever the right side expression makes sense (see concept of equality conditional to existence of one side): $\nabla (f g) (\bar{x}) = g (\bar{x}) \nabla (f) (\bar{x}) + f (\bar{x}) \nabla (g) (\bar{x})$ . Note that the products on the right side are scalar-vector function multiplications.
generic point, named functions, point-free notation	Suppose $f, g$ are both real-valued functions of a vector variable $\bar{x}$ . Then, we have the following product rule for gradient vectors wherever the right side expression makes sense (see concept of equality conditional to existence of one side): $\nabla (f g) = g \nabla (f) + f \nabla (g)$ . Note that the products on the right side are scalar-vector function multiplications.

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