Note: This discussion is about an older version of the COMSOL Multiphysics® software. The information provided may be out of date.
Discussion Closed This discussion was created more than 6 months ago and has been closed. To start a new discussion with a link back to this one, click here.
Using Cole-Cole expression to solve for frequency dependence of dielectric properties
Posted 02.06.2011, 12:15 GMT-4 RF & Microwave Engineering, Materials, Modeling Tools & Definitions, Parameters, Variables, & Functions Version 4.1 1 Reply
Please login with a confirmed email address before reporting spam
I am very new to the software and trying to learn my way around by doing tutorials. However there are some things that I cannot easily find.
I was wondering if anyone knew if it is possible to use the Cole-Cole expression to model the frequency dependence of the dielectric in tissue. The formula (forgive writing formulas in text) is:
e(w) = e(infinity) + SUMMATION(from 1 to 4) expression.
I am also wondering if anyone knows how to set up an electromagnetic wave as a Gaussian pulse. I am trying Transient Electromagnetic Wave physics.
Any help is greatly appreciated,
John
Hello John Bordelon
Your Discussion has gone 30 days without a reply. If you still need help with COMSOL and have an on-subscription license, please visit our Support Center for help.
If you do not hold an on-subscription license, you may find an answer in another Discussion or in the Knowledge Base.
Please login with a confirmed email address before reporting spam
Under
Electromagnetic Waves -> Wave Equation -> Electric Displacement Field -> Electric Displacement Field Model
choose the "Dielectric Losses" option. This will activate the real and imaginary part of relative permittivity
requirement for material properties. You can then enter your cole-cole equations in the material parameters
epsilonBis and epsilonPrim. For example, muscle tissue can be modeled over the microwave band by these equations:
Real part
(55.32+1.0131763650973007E-8*freq^0.875+2.3290263939139233E-18*freq^1.75)/(1.+3.47871713338129E-10*freq^0.875+7.948895542368339E-19*freq^1.75)
Imaginary part
-(-1.3966655477570145E10-4.858604370585691*freq^0.875-1.1101948546745167E-8*freq^1.75-4.581162876363306E-8*freq^1.875)/(freq*(1.+3.47871713338129E-10*freq^0.875+7.948895542368339E-19*freq^1.75))
Be careful that you don't have a "conductivity" defined for the material that is redundant with the Cole Cole model.
I set conductivity to zero and put everything in epsilon. Also, the imaginary part of epsilon is actually the negative of the imaginary part. For most materials, epsilonBis should be a *positive* number in Comsol. Note the extra minus
sign in the formula above for the Imaginary part. Power dissipation should be positive in material. If you see negative power dissipation, you probably have the sign of the imaginary part of permittivity wrong.
As far as Gaussean pulse goes, it sounds to me like you should be using CST rather than COMSOL. Also, if
you use CST the Cole-Cole equations are built in for first and second order models. You just need to enter the parameters. And plane wave illuminations with absorbing boundaries are easier in CST.
But COMSOL makes nicer plots.