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gerber2ems - openEMS simulation based on Gerber files

Copyright (c) 2023 Antmicro

This project aims to streamline signal integrity simulations using open source tools. It takes PCB production files as input (Gerber, drill files, stackup information) and simulates trace SI performance using openEMS - a free and open electromagnetic field solver that uses the FDTD method.

Installation

Required dependencies

1. OpenEMS

Install the following packages (on Debian/Ubuntu):

sudo apt install build-essential cmake git libhdf5-dev libvtk9-dev libboost-all-dev libcgal-dev libtinyxml-dev qtbase5-dev libvtk9-qt-dev python3-numpy python3-matplotlib cython3 python3-h5py

Clone the repository, compile and install OpenEMS:

git clone --recursive https://github.com/thliebig/openEMS-Project.git
cd openEMS-Project
./update_openEMS.sh ~/opt/openEMS --python

2. Gerbv

For Ubuntu/Debian:

sudo apt install gerbv

Optional dependecies

1. Paraview

For Ubuntu/Debian:

sudo apt install paraview

Script installation

It is suggested to update pip before installation.

python3 -m pip install pip -U

To install the script, run the commands below:

git clone https://github.com/antmicro/gerber2ems.git
cd ./gerber2ems
pip install .

Virtual environment

To install the script along with its Python dependencies inside a virtual environment on Debian/Ubuntu you can follow these steps:

For the script installed inside virtual environment to be accessible globally without the need to manually enable the virtual environment, you can create a bash script as follows:

#!/usr/bin/env bash
source /path/to/repository/.venv/bin/activate
python3 /path/to/repository/src/gerber2ems/main.py "$@"
deactivate

Then:

Then, you can simply call gerber2ems to run the script from any location.

Usage

For quick lookup, use gerber2ems --help.

To simulate a trace, follow these steps:

Results

This software returns the following types of output:

Impedance chart

Plot of each excited port vs. frequency.

S-parameter chart

Plot of each S-parameter measured during each excitation.

Smith chart

Plot of parameter S-11 for each excitation.

S-parameter and impedance data

Impedance and S-parameter data gathered during the simulations, stored in CSV format with a header.

How it works

Project preparation

Simulating the whole PCB is extremely resource-intensive, so it is important to separate a region of interest as small in size as possible. Uneeded traces, pours etc., should be removed. If entire layers are redundant, they can be removed in later steps.

Ports of interest should be marked by a virtual component in positions files. Their designator should begin with "SP" and be followed by port number.

Origin point for drill files should be placed in bottom-left corner.

Every trace or pour that is somehow terminated in reality and will exist in the simulation should also be terminated using a simulation port or connected to ground.

For now, capacitors are not simulated and, for high frequency simulation, they can be aproximated by shorting them using a trace.

PCB input files preparation

This script requires multiple input files for geometry creation. They should all reside in the "fab" folder and are listed below:

{
    "layers": [
        {
            "name": "F.Cu",
            "type": "copper",
            "color": null,
            "thickness": 0.035,
            "material": null,
            "epsilon": null,
            "lossTangent": null
        },
        {
            "name": "dielectric 1",
            "type": "core",
            "color": null,
            "thickness": 0.2,
            "material": "FR4",
            "epsilon": 4.5,
            "lossTangent": 0.02
        }
    ],
    "format_version": "1.0"
}
# Ref     Val              Package                PosX       PosY       Rot  Side
SP1       Simulation_Port  Simulation_Port      3.0000    11.7500  180.0000  top

Config preparation

The simulation.json file configures the entire simulation. You can find sample files in the example_gerbers folder. All dimensions in this file are specified in micrometers. This config file constitutes of three sections:

Miscellaneous
Mesh
Ports

ports is a list of ports. Each port has the following parameters:

Geometry creation

This is an automatic step done with the -g flag. The script locates all the files needed for creating the geometry (Gerbers, drill files, pnp files, stackup file, simulation config file). Then it converts Gerber files to PNG using gerbv. The PNG's are then processed into triangles and input into the geometry. This also adds via geometries as well as port geometries. Everything is placed on correct Z heights using the stackup file.

You can view the generated geometry which is saved to ems/geometry/geometry.xml using AppCSXCAD (installed during OpenEMS installation).

Simulation

This is an automatic step commenced with the -s flag. The script loads the geometry and config files. It inputs all the information into the engine and starts the simulations, iterating over every "excited" port.

At this step, the user should verify if the indicated number of timesteps is enough. The engine recommends that it should be at least 3x as long as the pulse:

Excitation signal length is: 3211 timesteps (3.18343e-10s)
Max. number of timesteps: 10000 ( --> 3.11429 * Excitation signal length)

The simulator converts the geometry into voxels and starts solving the Maxwell equations for each edge in the mesh. It does that for a number of timesteps (maximum number specified in config) and then exits. For each timestep, electric field data from planes between copper planes is saved to files in the ems/simulation folder. Port voltage and current data is also saved.

During the simulation, one of the ports is exited using a gaussian pulse (wideband frequency content). This pulse traverses the network and exits using ports (it can also get emitted outside the board).

You can monitor the simulation by looking at the engine output:

[@ 20s] Timestep: 4620 || Speed:  294.4 MC/s (3.372e-03 s/TS) || Energy: ~4.16e-16 (- 7.15dB)

This way you can see:

After the simulation finishes, the user can verify the data using Paraview (described in a section below).

Postprocessing

This is an automatic step commenced with the -p flag. The script is loaded in the simulator data for each excited port. It then computes an FFT to get data in the frequency domain. It then converts the incident and reflected wave data to impedance and S parameters. These are saved in CSV format in the ems/results/S-parameters folder. This data is also automatically plotted and the plots are saved to ems/results.

Paraview

To view simulation data in Paraview, follow these steps:

Licensing

This project is published under the Apache-2.0 license.