It uses first-principle physics (Maxwell’s equations) rather than simplified empirical formulas. This makes it reliable for even the most complex geometries.
Its ability to model non-uniform soil (multilayers, vertical layers, and hemispherical structures) is far superior to basic tools.
Unlike general-purpose simulation tools, CDEGS is specifically built to solve complex problems related to the interaction between electrical networks and the physical environment (soil, air, and infrastructure). It is used extensively by utility companies, consulting engineers, and research laboratories worldwide to ensure safety and compliance with standards such as IEEE 80, IEC 62305, and EN 50522.
: Evaluates ground potential rise (GPR), touch and step voltages, and grounding grid impedance.
It uses first-principle physics (Maxwell’s equations) rather than simplified empirical formulas. This makes it reliable for even the most complex geometries.
Its ability to model non-uniform soil (multilayers, vertical layers, and hemispherical structures) is far superior to basic tools.
Unlike general-purpose simulation tools, CDEGS is specifically built to solve complex problems related to the interaction between electrical networks and the physical environment (soil, air, and infrastructure). It is used extensively by utility companies, consulting engineers, and research laboratories worldwide to ensure safety and compliance with standards such as IEEE 80, IEC 62305, and EN 50522.
: Evaluates ground potential rise (GPR), touch and step voltages, and grounding grid impedance.