This app is an interactive educational tool that uses a visualizer to demonstrate and verify key vector calculus concepts. It showcases Euler's Homogeneous Function Theorem for vector fields, proving the identity $(x \cdot \nabla) v=n v$ for different homogeneous vector fields. The tool further applies this principle to compute the divergence of a more complex vector expression, simplifying $\nabla \cdot\{x[x \cdot v]\}$ to $(n+4)(x \cdot v)$. By bridging abstract theory with a dynamic, real-time visualization and calculation, the app makes complex mathematical relationships tangible and easy to understand.
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$\gg$Mathematical Structures Underlying Physical Laws
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The central point is that for a homogeneous vector field $v$ of degree $n$, a special relationship exists: the directional derivative in the direction of the position vector $x$ is simply the vector field itself scaled by the degree of homogeneity. This is a direct application of Euler's Homogeneous Function Theorem, and it is expressed by the identity:
$$ (x \cdot \nabla) v=n v $$
This identity is powerful because it allows us to simplify a differential operation into a simple algebraic one, which is key to solving more complex problems.
The second part of the analysis shows how the core identity is used to solve a much more complex problem: computing the divergence $\nabla \cdot\{x[x \cdot v]\}$. The solution relies on a chain of established vector calculus rules, specifically the product rule for divergence and the product rule for the gradient of a dot product. By systematically simplifying each term, the analysis leads to a surprisingly clean final result:
$$ \nabla \cdot\{x[x \cdot v]\}=(n+4)(x \cdot v) $$
This demonstrates how foundational theorems like Euler's can be combined with standard vector calculus identities to derive new, elegant relationships in the field.
This app is a teaching tool that visualizes and verifies the Homogeneous Function Theorem for vector fields. It shows how different vector fields behave and proves that the identity $( x \nabla) v=n v$ holds true for each one. The demo lets you see abstract math concepts come to life with real-time calculations.
the Homogeneous Function Theorem for vector fields
the Homogeneous Function Theorem for vector fields
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Proving the Cross Product Rules with the Levi-Civita Symbol
Proving the Epsilon-Delta Relation and the Bac-Cab Rule
Simplifying Levi-Civita and Kronecker Delta Identities
Why a Cube's Diagonal Angle Never Changes
How the Cross Product Relates to the Sine of an Angle
Finding the Shortest Distance and Proving Orthogonality for Skew Lines
A Study of Helical Trajectories and Vector Dynamics
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Divergence and Curl Analysis of Vector Fields
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Commutativity and Anti-symmetry in Vector Calculus Identities
Double Curl Identity Proof using the epsilon-delta Relation
The Orthogonality of the Cross Product Proved by the Levi-Civita Symbol and Index Notation
Surface Parametrisation and the Verification of the Gradient-Normal Relationship
Proof and Implications of a Vector Operator Identity
Conditions for a Scalar Field Identity
Solution and Proof for a Vector Identity and Divergence Problem
Kinematics and Vector Calculus of a Rotating Rigid Body
Work Done by a Non-Conservative Force and Conservative Force
The Lorentz Force and the Principle of Zero Work Done by a Magnetic Field
Calculating the Area of a Half-Sphere Using Cylindrical Coordinates
Divergence Theorem Analysis of a Vector Field with Power-Law Components
Total Mass in a Cube vs. a Sphere
Momentum of a Divergence-Free Fluid in a Cubic Domain
Total Mass Flux Through Cylindrical Surfaces
Analysis of Forces and Torques on a Current Loop in a Uniform Magnetic Field
Computing the Integral of a Static Electromagnetic Field
Surface Integral to Volume Integral Conversion Using the Divergence Theorem
Circulation Integral vs. Surface Integral
Using Stokes' Theorem with a Constant Scalar Field
Verification of the Divergence Theorem for a Rotating Fluid Flow
Integral of a Curl-Free Vector Field
Boundary-Driven Cancellation in Vector Field Integrals
Proving the Generalized Curl Theorem
Computing the Magnetic Field and its Curl from a Dipole Vector Potential
Proving Contravariant Vector Components Using the Dual Basis
Verification of Orthogonal Tangent Vector Bases in Cylindrical and Spherical Coordinates
Vector Field Analysis in Cylindrical Coordinates
Vector Field Singularities and Stokes' Theorem
Compute Parabolic coordinates-related properties
Analyze Flux and Laplacian of The Yukawa Potential
Verification of Vector Calculus Identities in Different Coordinate Systems
Analysis of a Divergence-Free Vector Field
The Uniqueness Theorem for Vector Fields
Analysis of Electric Dipole Force Field
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