Whitepaper – Predicting Electromagnetic Interference and Compatibility

Electromagnetic Interference and Compatibility can not only impact the performance of a device but can delay device certification and time to market. Neither of these outcomes are acceptable to companies in the fast paced, competitive market of today. This whitepaper is an overview of Electromagnetic Interference and Compatibility (EMI/EMC):

Download Whitepaper

ANSYS HFSS and ANSYS SIwave are the state of the art tools for evaluating EM Interference and Compatibility.

Industry Solutions

Our industry solution pages are the perfect primer on the simulation benefits and concerns by industry. Check often for relevant whitepapers like above, videos and workshop problems available for download. The industries most related to this post would be:

  • Antenna Design – Antenna integration is a complex multi-scale and multi-domain problem. Make sure your antenna is performing the way it is supposed to with ANSYS Simulation.
  • Internet of Things – An IoT device that doesn’t deal with EMI is just a thing. Make sure your device works in the outside world.

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Tech Tip: Structural Boundary Condition Types

Did you know that there are three main ways to apply force and displacement in a structural analysis? They are:

  • loadDisplacement/Force – Most straightforward, least amount of setup work.
  • remote_loadRemote Displacement/Remote Force – Rigid/Deformable/Coupled behaviors available for scoped face, able to apply a rotation displacement.
  •  Nodal Displacement/Nodal Force – Can add to a model and still do a nonlinear restart, not necessary to scope to a geometry entity.

What are the different behaviors and how can you add a new load to an analysis you wish to restart? Read more below:

Remote Displacement Behaviors

There are three behaviors available with remote boundary conditions:

The same force is applied with 3 different behaviors with a remote boundary condition: Rigid - The face shape is not allowed to deform, Deformable - Load is distributed to the nodes of the face weighted by the distance from the remote point, Coupled - The specified degree of freedom solutions are equal across the entire face

A remote force with the same magnitude & direction is applied with 3 different behaviors :
Rigid – The face shape is not allowed to deform.
Deformable – Load is distributed to the nodes of the face weighted by the distance from the remote point.
Coupled – The specified degree of freedom solutions are equal across the entire face.

The remote boundary conditions are implemented with the Multipoint Constraint (MPC) technology. For more information, see the corresponding section in the Contact Technology Guide of the ANSYS documentation.

Nonlinear Restarts

All of the above loads are compatible with nonlinear restarts but only tabular data after the desired restart point may be modified and only on a pre-existing load. This is because the regular and remote loads actually create surface effect elements (SURF154) to implement the load behind the scenes. While this confers several benefits, such as the ability to have overlapping loads on the same face, it is not compatible with nonlinear restarts since adding new elements would change the model too much. Direct forces and pressures are applied directly to the nodes, however, and avoid this restriction. This functionality is not available for direct displacements since a displacement of 0 is a constraint and would invalidate the restart points.

To add an entirely new load (force/pressure only) to an analysis:

  1. To ensure that restart points are available make sure to set Analysis Settings -> Restart Controls -> Retain Files After Full Solve to Yes
  2. Add a load step by setting increasing the number in Analysis Settings -> Step Controls -> Number of Steps
  3. Create a nodal named selection of the desired load location, either through the Named Selection Worksheet or the Mesh Selection capabilities in Mechanical
  4. Insert a Nodal Force or Nodal Pressure into the analysis and scope it to the above nodal named selection
  5. Modify only the tabular data for load steps that are not yet solved for!
  6. Solve the analysis (should do restart automatically, if not set it in Analysis Settings -> Restart Analysis)

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