Acculution ApS
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Posted:
3 years ago
21 dic 2021, 05:16 GMT-5
I think you need to use the 'with' operator to grab hold on the first eigenvalue; see documentation or below:
WITH
•
The with operator can access specific solutions during results evaluation.
•
For time-dependent problems, parametric problems, and eigenvalue problems, this makes it possible to use the solution at any of the time steps, any parameter value, or any eigensolution in an expression used for plotting or data evaluation. To evaluate a sum (average) of displacement for the first six eigenmodes above the rigid-body modes in a 3D solid mechanics model, for example, use sum(with(m,(1/(m+1))*solid.disp),m,7,12), where m is the summation index, summing the displacements, divided by m+1 to form the average, from eigenmode 7 to eigenmode 12.
•
Use the solution number as the first input argument. The second input argument is the expression that you want to evaluate using this solution. For example, with(3,u^2) provides the square of the third eigensolution for an eigenvalue problem.
•
You can also use 'first' or 'last' as the first argument to evaluate an expression at the first or last time of the simulation, respectively.
•
For example, you can use the with operator to verify that two eigensolutions are orthogonal or to compare two solutions at different time steps or parameter values.
•
If you want to use the with operator for a parametric problem, you should use a Parametric solver instead of a Parametric Sweep.
•
The with operator can only be used during results evaluation, so you cannot use it when setting up the model.
See also withsol for a more general operator.
-------------------
René Christensen, PhD
Acculution ApS
www.acculution.com
info@acculution.com
I think you need to use the 'with' operator to grab hold on the first eigenvalue; see documentation or below:
WITH
•
The with operator can access specific solutions during results evaluation.
•
For time-dependent problems, parametric problems, and eigenvalue problems, this makes it possible to use the solution at any of the time steps, any parameter value, or any eigensolution in an expression used for plotting or data evaluation. To evaluate a sum (average) of displacement for the first six eigenmodes above the rigid-body modes in a 3D solid mechanics model, for example, use sum(with(m,(1/(m+1))*solid.disp),m,7,12), where m is the summation index, summing the displacements, divided by m+1 to form the average, from eigenmode 7 to eigenmode 12.
•
Use the solution number as the first input argument. The second input argument is the expression that you want to evaluate using this solution. For example, with(3,u^2) provides the square of the third eigensolution for an eigenvalue problem.
•
You can also use 'first' or 'last' as the first argument to evaluate an expression at the first or last time of the simulation, respectively.
•
For example, you can use the with operator to verify that two eigensolutions are orthogonal or to compare two solutions at different time steps or parameter values.
•
If you want to use the with operator for a parametric problem, you should use a Parametric solver instead of a Parametric Sweep.
•
The with operator can only be used during results evaluation, so you cannot use it when setting up the model.
See also withsol for a more general operator.
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Posted:
3 years ago
2 gen 2022, 22:35 GMT-5
Updated:
3 years ago
2 gen 2022, 22:35 GMT-5
I'll try this way :)
Thank you very much!
I'll try this way :)
Thank you very much!
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Posted:
3 years ago
24 mar 2022, 04:53 GMT-4
Hello,
I tried this way but got some troubles:
My objective function is min. (withsol('sol1',freq,setind(lambda,1))-500[Hz])^2 and control parameter is DP_E which means Young's modulus of diaphragm.
But the optimized result didn't change, it's still the same as the initial DP_E.
Did I miss something?
Thank you in advanced.
Hello,
I tried this way but got some troubles:
My objective function is min. (withsol('sol1',freq,setind(lambda,1))-500[Hz])^2 and control parameter is DP_E which means Young's modulus of diaphragm.
But the optimized result didn't change, it's still the same as the initial DP_E.
Did I miss something?
Thank you in advanced.