Engineers rely on the accuracy, capacity, and performance of HFSS to design high-speed components including on-chip embedded passives, IC packages, PCB interconnects, and high-frequency components such as antennas, RF/microwave components, and biomedical devices. With HFSS, engineers can extract parasitic parameters (S, Y, Z), visualize 3D electromagnetic fields (near- and far-field) and generate Full-Wave SPICE™ models that link to circuit simulations. Signal Integrity engineers' use HFSS within established EDA design flows to evaluate signal quality, including transmission path losses, reflection loss due to impedance mismatches, parasitic coupling and radiation. To solve the most demanding high-frequency simulations all of the HFSS solvers are equipped with High-Performance Computing (HPC) options including Domain Decomposition and Distributed Processing. These HPC options will decrease computation time and leverage existing computer resources to solve very large simulations. HFSS provides unprecedented integration with EDA design flows allowing engineers to combine complex, highly nonlinear circuits with transistor-level detail with 3D full-wave accurate component models to solve challenging high-performance electronic designs. With HFSS Solver on Demand users can operate HFSS from an easy-to-use, stack-up based layout interface, provides direct import of layered geometry and automated set-up. AnsoftLinks offers another option to transfer 3D ECAD or MCAD component geometry to HFSS. For in-depth multiphysics analysis HFSS is integrated with ANSYS Workbench. HFSS designs exist as data blocks in the ANSYS Workbench interface allowing for easy data exchange with ANSYS Mechanical, ANSYS Icepak and more. This link also provides tighter integration with ANSYS DesignXplorer to facilitate optimization and design of experiment studies