Analog Insydes is a Mathematica toolbox for modeling, analysis, and design of analog electronic circuits, tailored specifically for industrial applications. Based on a hierarchical netlist description language, you can describe both linear and nonlinear circuits as well as control systems, and automatically set up equation systems in the frequency and time domains. A unique feature of Analog Insydes is its capability to compute approximated symbolic formulas for linear and nonlinear circuit characteristics, drastically reducing the complexity of symbolic expressions while controlling a user-given error bound.

Design of filters by Analog Insydes

With its numerous import and export capabilities, Analog Insydes is very well integrated into industrial design frameworks, for example by allowing the import of netlists, simulation data, and circuit schematics into your Analog Insydes session. An extensive symbolic model library for circuit elements including BJT and MOSFET devices is provided in different complexity levels and can be extended by the user by means of the flexible Analog Insydes device modeling language.

Standard numerical circuit analyses like AC, DC-transfer, transient, or pole/zero analysis and many specialized graphics commands for electronic applications like Bode plots or Root locus plots let you easily verify your results within your Analog Insydes environment.

 

 

Model order reduction by Analog Insydes

The combination of the unique symbolic approximation capabilities and the numeric and graphic commands together with the import/export filters into one integrated environment make Analog Insydes a powerful tool which allows you to obtain new insights into your circuit's behavior.

Additionally, the package is an ideal tool for teaching circuit analysis in engineering education because it provides an unrestricted set of primitive linear circuit elements (including all types of controlled sources) and permits full access to device models and circuit equations.