Diffusion Mathematics: Difference between revisions

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In no particular order, here are some common mathematical concepts often found in diffusion modeling. To simulate and quantify simple diffusion (e.g. 2D Brownian Motion) only requires a working knowledge of basic statistics and trigonometry. Modeling complex forms of diffusion requires the use of vector calculus and differential geometry. There is a thin boundary between simple and complex diffusion and the math becomes dense very quickly. For example, using just a few lines of code, one can easily simulate stochastic diffusion on a flat 2D surface:
In no particular order, here are some common mathematical concepts often found in diffusion modeling. To simulate and quantify simple diffusion (e.g. 2D Brownian Motion) only requires a working knowledge of basic statistics and trigonometry. Modeling complex forms of diffusion requires the use of integral and vector calculus and differential geometry. There is a thin boundary between simple and complex diffusion and the math becomes dense very quickly. For example, using just a few lines of code, one can easily simulate stochastic diffusion on a flat 2D surface:
 
 


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==Partial Derivatives==
==Partial Derivatives==
In mathematics, a partial derivative of a function of several variables is its derivative with respect to one of those variables, with the others held constant (as opposed to the total derivative, in which all variables are allowed to vary). Partial derivatives are used in vector calculus and differential geometry.
In mathematics, a [http://en.wikipedia.org/wiki/Partial_derivative partial derivative] of a function of several variables is its derivative with respect to one of those variables, with the others held constant (as opposed to the total derivative, in which all variables are allowed to vary). Partial derivatives are used in vector calculus and differential geometry.
 


[[File:Partial Derivative 3D.png]]
[[File:Partial Derivative 3D.png]]
[[File:Partial Derivative 2D.png]]
[[File:Partial Derivative 2D.png]]
The partial derivative of a function f with respect to the variable x is variously denoted by:
[[File:Partial derivative eq1.png]]
Read as: del F with respect to X equals...


Suppose that ƒ is a function of more than one variable. For instance:
Suppose that ƒ is a function of more than one variable. For instance:


[[File:Partial derivative eq1.png]]
[[File:Partial derivative eq2.png]]


The graph of this function defines a surface in Euclidean space. To every point on this surface, there are an infinite number of tangent lines. Partial differentiation is the act of choosing one of these lines and finding its slope. Usually, the lines of most interest are those that are parallel to the xz-plane, and those that are parallel to the yz-plane (which result from holding either y or x constant, respectively.)
The graph of this function defines a surface in Euclidean space. To every point on this surface, there are an infinite number of tangent lines. Partial differentiation is the act of choosing one of these lines and finding its slope. Usually, the lines of most interest are those that are parallel to the xz-plane, and those that are parallel to the yz-plane (which result from holding either y or x constant, respectively.)
To find the slope of the line tangent to the function at P(1, 1, 3) that is parallel to the xz-plane, the y variable is treated as constant. The graph and this plane are shown on the right. On the graph below it, we see the way the function looks on the plane y = 1. By finding the derivative of the equation while assuming that y is a constant, the slope of ƒ at the point (x, y, z) is found to be:
To find the slope of the line tangent to the function at P(1, 1, 3) that is parallel to the xz-plane, the y variable is treated as constant. The graph and this plane are shown on the right. On the graph below it, we see the way the function looks on the plane y = 1. By finding the derivative of the equation while assuming that y is a constant, the slope of ƒ at the point (x, y, z) is found to be:


[[File:Partial derivative eq2.png]]
[[File:Partial derivative eq4.png]]


So at (1, 1, 3), by substitution, the slope is 3. Therefore
So at (1, 1, 3), by substitution, the slope is 3. Therefore
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at the point (1, 1, 3). That is, the partial derivative of z with respect to x at (1, 1, 3) is 3.
at the point (1, 1, 3). That is, the partial derivative of z with respect to x at (1, 1, 3) is 3.


==Laplace Operator==


==Laplace Operator==


{{ExpandBox|Laplace operator|
In mathematics the [http://en.wikipedia.org/wiki/Laplacian Laplace operator] or Laplacian is a differential operator given by the divergence of the gradient of a function on Euclidean space. It is usually denoted by the nabla symbols ∇·∇, ∇2 or ∆. The Laplacian ∆f(p) of a function f at a point p, up to a constant depending on the dimension, is the rate at which the average value of f over spheres centered at p, deviates from f(p) as the radius of the sphere grows.
In mathematics the Laplace operator or Laplacian is a differential operator given by the divergence of the gradient of a function on Euclidean space. It is usually denoted by the symbols ∇·∇, ∇2 or ∆. The Laplacian ∆f(p) of a function f at a point p, up to a constant depending on the dimension, is the rate at which the average value of f over spheres centered at p, deviates from f(p) as the radius of the sphere grows.
 
}}<!-- END ARTICLE -->
{{ExpandBox|more info or media|
No additional media
}}
 
==Gradients==
[[File:Gradient Math.png|right]]
 
The [http://en.wikipedia.org/wiki/Gradient gradient] (or gradient vector field) of a scalar function ''f(x1, x2, x3, ..., xn)'' is denoted ∇f or <sup>→</sup>&nabla;f where ∇ (the nabla symbol) denotes the vector differential operator, del. The notation "grad(f)" is also commonly used for the gradient. The gradient of f is defined as the unique vector field whose dot product with any vector v at each point x is the directional derivative of f along v. That is,
 
[[File:Gradient Eq1.png]]
 
In a rectangular coordinate system, the gradient is the vector field whose components are the partial derivatives of f:
 
[[File:Gradient Eq2.png]]
 
where the ei are the orthogonal unit vectors pointing in the coordinate directions. When a function also depends on a parameter such as time, the gradient often refers simply to the vector of its spatial derivatives only.
In the three-dimensional Cartesian coordinate system, this is given by
 
[[File:Gradient Eq3.png]]
 
where i, j, k are the standard unit vectors. For example, the gradient of the function
 
[[File:Gradient Eq4.png]]
 
is:
 
[[File:Gradient Eq5.png]]


In some applications it is customary to represent the gradient as a row vector or column vector of its components in a rectangular coordinate system.






[[Category:ReDiClus]] [[Category:Diffusion]] [[Category:Statistics]]
[[Category:ReDiClus]] [[Category:Diffusion]] [[Category:Statistics]][[Category:Math]][[Category:Neurobiology]]

Latest revision as of 21:22, 9 August 2014

In no particular order, here are some common mathematical concepts often found in diffusion modeling. To simulate and quantify simple diffusion (e.g. 2D Brownian Motion) only requires a working knowledge of basic statistics and trigonometry. Modeling complex forms of diffusion requires the use of integral and vector calculus and differential geometry. There is a thin boundary between simple and complex diffusion and the math becomes dense very quickly. For example, using just a few lines of code, one can easily simulate stochastic diffusion on a flat 2D surface:



% MATLAB CODE %
Ndots = 100; Nsteps = Ndots;
D = .5;                     % Diffusion Rate
dm = 2;                     % dimensions
tau = 1;                    % time step
k = sqrt(dm*D*tau);         % stdev of step-size distribution
xyl = ones(2,Ndots); xyds = xyl;

for t = 1:Nsteps
   xyds = (k * randn(2,Ndots));
   for j = 1:Ndots
     xyl(:,j) = xyl(:,j)+xyds(:,j);
   end
   gscatter(xyl(1,:),xyl(2,:));
end

On the other hand, simulating stochastic diffusion on a ruffled 2D membrane is often done using parallel-computing systems at your local university's supercomputer center. However, with an understanding of the mathematical concepts that underlie complex diffusion, we can understand diffusion properties without a powerful computing cluster. I am a neuroscientist, not a mathematician or physicist, and based on my own personal trials and tribulations in modeling diffusion as a non-math expert, here are some concepts I needed to brush up on before getting serious about diffusion modeling...




Partial Derivatives

In mathematics, a partial derivative of a function of several variables is its derivative with respect to one of those variables, with the others held constant (as opposed to the total derivative, in which all variables are allowed to vary). Partial derivatives are used in vector calculus and differential geometry.



The partial derivative of a function f with respect to the variable x is variously denoted by:

Read as: del F with respect to X equals...

Suppose that ƒ is a function of more than one variable. For instance:

The graph of this function defines a surface in Euclidean space. To every point on this surface, there are an infinite number of tangent lines. Partial differentiation is the act of choosing one of these lines and finding its slope. Usually, the lines of most interest are those that are parallel to the xz-plane, and those that are parallel to the yz-plane (which result from holding either y or x constant, respectively.) To find the slope of the line tangent to the function at P(1, 1, 3) that is parallel to the xz-plane, the y variable is treated as constant. The graph and this plane are shown on the right. On the graph below it, we see the way the function looks on the plane y = 1. By finding the derivative of the equation while assuming that y is a constant, the slope of ƒ at the point (x, y, z) is found to be:

So at (1, 1, 3), by substitution, the slope is 3. Therefore

at the point (1, 1, 3). That is, the partial derivative of z with respect to x at (1, 1, 3) is 3.

Laplace Operator

In mathematics the Laplace operator or Laplacian is a differential operator given by the divergence of the gradient of a function on Euclidean space. It is usually denoted by the nabla symbols ∇·∇, ∇2 or ∆. The Laplacian ∆f(p) of a function f at a point p, up to a constant depending on the dimension, is the rate at which the average value of f over spheres centered at p, deviates from f(p) as the radius of the sphere grows.

more info or media


No additional media

Gradients

The gradient (or gradient vector field) of a scalar function f(x1, x2, x3, ..., xn) is denoted ∇f or ∇f where ∇ (the nabla symbol) denotes the vector differential operator, del. The notation "grad(f)" is also commonly used for the gradient. The gradient of f is defined as the unique vector field whose dot product with any vector v at each point x is the directional derivative of f along v. That is,

In a rectangular coordinate system, the gradient is the vector field whose components are the partial derivatives of f:

where the ei are the orthogonal unit vectors pointing in the coordinate directions. When a function also depends on a parameter such as time, the gradient often refers simply to the vector of its spatial derivatives only. In the three-dimensional Cartesian coordinate system, this is given by

where i, j, k are the standard unit vectors. For example, the gradient of the function

is:

In some applications it is customary to represent the gradient as a row vector or column vector of its components in a rectangular coordinate system.