* A unified simulation environment for modeling virtually any type of
continuous-time (ode), discrete-time (digital), hybrid or multi-rate
* A flexible "open system" architecture that allows for the creation
of application specific modeling functions or a hook up to external
Fortran scientific resources or components written in C or C++.
* A comprehensive collection of built-in modeling components to
help simulate dynamic effects of diverse physical phenomena such
as rotational (quaternion) kinematics or asynchronous digital filters.
* High performance, matrix exponential based, recursive propagators
that ensure high fidelity simulation, fast execution, unlimited
model size (up to system limits), and full hierarchical invariance.
* Complete support for "scripting" (describing) simulation/analysis
activities which gives the power to conduct experiments of any
complexity in either automatic or interactive mode.
* Run-time (on-the-fly) selection of variables for graphic and numeric
display, including selective data logging to disk files.
* Ability to interactively control simulation execution, including
run-time selection of computational speed modes - from slow motion to
real-time to fast forward at processor capacity.
* Full support for application specific toolboxes (custom built or
imported) enabling rapid development of applications for multi-physics
processes, including unfettered reuse of extensive software resources on
* Full control over the modeling and simulation process instead of the other
way around. Prototyping, experimentation or testing of alternate designs is
free from the constraints of the complex graphical code mix "featured"
* Ability to convert legacy applications, evolutionary models, or static
computation tasks into Visual applications (Windows native) without
writing a single line of Win32 API code.
* Compatible with Compaq Visual Fortran (CVF) compiler and seamlessly
integrated with Microsoft Visual Studio development environment.