Vector Calculus Identities
The list of Vector Calculus Identities have been tabulated under three categories.
Gradient Function Identities
The Gradient Function Identities are tabulated below:
[Tex]\vec{\nabla} [/Tex](f + g) | [Tex]\vec{\nabla} [/Tex]f + [Tex]\vec{\nabla} [/Tex]g |
---|---|
[Tex]\vec{\nabla} [/Tex](cf) | c[Tex]\vec{\nabla} [/Tex]f, where C is constant |
[Tex]\vec{\nabla} [/Tex](fg) | f[Tex]\vec{\nabla} [/Tex]g + g[Tex]\vec{\nabla} [/Tex]f |
[Tex]\vec{\nabla} [/Tex](f/g) | (g[Tex]\vec{\nabla} [/Tex]f – f[Tex]\vec{\nabla}g [/Tex])/g2 at point [Tex]\vec{x} [/Tex]where g([Tex]\vec{x} [/Tex]) ≠ 0 |
[Tex]\vec{\nabla}(\vec{F}+\vec{G}) [/Tex] | [Tex]\vec{F} \times(\vec{\nabla} \times \vec{G})-(\vec{\nabla} \times \vec{F}) \times \vec{G}+(\vec{G} \cdot \vec{\nabla}) \vec{F}+(\vec{F} \cdot \vec{\nabla} [/Tex] |
Divergence Function Identities
The identity formula for Divergence Function is tabulated below:
[Tex]\vec{\nabla}(\vec{F}+\vec{G}) [/Tex] | [Tex]\vec{\nabla} \cdot \vec{F}+\vec{\nabla} \cdot \vec{G} [/Tex] |
---|---|
[Tex]\vec{\nabla} \cdot(c \vec{F}) [/Tex] | [Tex]c \vec{\nabla} \cdot \vec{F} [/Tex] |
[Tex]\vec{\nabla} \cdot(f \vec{F}) [/Tex] | [Tex]f \vec{\nabla} \cdot \vec{F}+\vec{F} \cdot \vec{\nabla} [/Tex] |
[Tex]\vec{\nabla} \cdot(\vec{F} \times \vec{G}) [/Tex] | [Tex]\vec{G} \cdot(\nabla \times \vec{F})-\vec{F} \cdot(\nabla \times \vec{G}) [/Tex] |
Curl Function Identities
The identities for curl function is tabulated below:
[Tex]\vec{\nabla} \times(\vec{F}+\vec{G}) [/Tex] | [Tex]\nabla \times \vec{F}+\vec{\nabla} \times \vec{G} [/Tex] |
---|---|
[Tex]\vec{\nabla} \times(c \vec{F}) [/Tex] | [Tex]c \vec{\nabla} \times \vec{F} [/Tex] |
[Tex]\vec{\nabla} \times(f \vec{F}) [/Tex] | [Tex]f \vec{\nabla} \times \vec{F}+\vec{\nabla} f \times \vec{F} [/Tex] |
[Tex]\vec{\nabla} \times(\vec{F} \times \vec{G}) [/Tex] | [Tex]\vec{F} \cdot(\vec{\nabla} \cdot \vec{G})-(\vec{\nabla} \vec{F}) \vec{G}+(\vec{G} \cdot \vec{\nabla}) \vec{F}-(\vec{F} \cdot \vec{\nabla}) [/Tex] |
Laplacian Function Identities
The identities for Laplacian Function is tabulated below:
[Tex]\vec{\nabla}^2(f+g) [/Tex] | [Tex]\vec{\nabla}^2 f+\vec{\nabla}^2 g [/Tex] |
---|---|
[Tex]\vec{\nabla}^2(c f) [/Tex] | [Tex]c \vec{\nabla}^2 f [/Tex], where C is a constant |
[Tex]\vec{\nabla}^2(f g) [/Tex] | [Tex]f \vec{\nabla}^2 g+2 \vec{\nabla} f \cdot g+g \vec{\nabla}^2 [/Tex] |
Degree Two Function Identities
The vector calculus identities for two degree function is tabulated below:
[Tex]\vec{\nabla} \cdot(\nabla \times \vec{F}) [/Tex] | 0 |
---|---|
[Tex]\vec{\nabla} \times(\vec{\nabla} f) [/Tex] | 0 |
[Tex]\vec{\nabla} \cdot(\overrightarrow{\nabla f} \times \overrightarrow{\nabla g}) [/Tex] | 0 |
[Tex]\vec{\nabla} \cdot(f \overrightarrow{\nabla g}-g \vec{\nabla}) [/Tex] | [Tex]f \vec{\nabla}^2 g-g \vec{\nabla}^2 f [/Tex] |
[Tex]\vec{\nabla} \times(\nabla \times \vec{F}) [/Tex] | [Tex]\vec{\nabla}(\vec{\nabla} \cdot \vec{F})-\vec{\nabla}^2 [/Tex] |
Vector Calculus in Maths
Vector Calculus in maths is a sub-division of Calculus that deals with the differentiation and integration of Vector Functions. We already know that Calculus is a branch of mathematics that deals with the rate of change of a function concerning another function. There are two major divisions of Calculus namely, Differential Calculus and Integral Calculus.
The branch of Differential Calculus deals with the process of finding derivatives or differentiation of functions while Integral Calculus deals with finding the antiderivative of a function whose derivative is given. In this article, we will learn in detail about Vector Calculus which is a lesser-known branch of calculus, and the basic formulas of Vector Calculus.
In this article, you are going to read everything about what is vector calculus in engineering mathematics, vector calculus formulas, vector analysis, etc.
Table of Content
- What is Vector Calculus?
- Operation in Vector
- Divergence and Curl
- Vector Calculus Formulas
- Vector Calculus Identities
- Vector Calculus Applications
- Solved Examples
- FAQs
Contact Us