HbmPFCL6Oa0/hqdefault.jpg' alt='Electromagnetic Simulation Software' title='Electromagnetic Simulation Software' />Integrand Software. About EMXEMX is an electromagnetic simulator for high frequency, RF, and mixed signal integrated circuits. Our unique emphasis is on complete automation coupled with uncompromised speed and accuracy. EMX has been benchmarked by our customers to be more than an order of magnitude faster than the leading finite element and boundary element tools in the industry. EMX is built on a philosophy of maximal automation, with industry standard input and output formats, full scriptability from the command line, and automated handling of modern IC layout features. EMX is a planar 3. D, integral equation solver that uses a very accurate representation of Maxwells equations. It features 3. D conductors and viastrue volumetric currents to accurately account for skin effectaccurate sidewall capacitanceslayered and lossy substrate effectssubstrate and inter component coupling. EMX is particularly easy to use even for complicated geometries in modern IC processes. It supports automated handling of mask ready layout, with no need for hand editing automatic merging techniques for via arrayscontext dependent viasslotting rulesmetal and dummy fillboolean operations for layer generationwidth and spacing dependent metal biasscaling operations to port technologies to half nodes. EMX is very efficient because of advanced numerics, such as Multipole accelerated far field interactions for fast matrix construction advanced meshing and compression techniques to reduce matrix memory requirements iterative solvers and robust preconditioning for quick matrix solutiona well conditioned matrix formulation, even at low frequencies automated reduced order modeling for fast frequency sweeps EMX is used by foundries and semiconductor design houses for tasks such as characterization of passive component librariesdesign of spiral inductors, MOM capacitors, MIM capacitors, baluns and transformers. Seadoo Millenium Edition Gtx on this page. Electromagnetic Simulation Software' title='Electromagnetic Simulation Software' />RF test structuresmodeling large distributed power transistors simulation of high Q passive in package filtersextraction of complete RF circuits. EMX is fully integrated into Cadence Virtuoso Interface for both Cadnce 5. Cadence 6. 1. Pcells for inductors, transformers, stacked inductors, pcells, tcoils. Cadence Design kit support for various foundries such at TSMC, IBM, GLOBALFOUNDRIES and UMCConvenient minimalist interface to Cadence. Examples using EMX. Electromagnetic Simulation Software' title='Electromagnetic Simulation Software' />Field Precision creates finiteelement simulation software for a broad spectrum of applications high voltage engineering, magnet design, chargedparticle devices. Altair provides leading electromagnetic simulation software from static to high frequency applications, including antenna design and placement, EMC and RCS. Electromagnetic Simulation Software' title='Electromagnetic Simulation Software' />Hyper. Works for Electromagnetic Simulation. Altair provides leading electromagnetic EM simulation software, widely used in many industries and applications to solve a broad range of electromagnetic problems from static to low and high frequencies. Altairs electromagnetics solver suites in Hyper. Works are FEKO and Flux, which are widely used across many industries including aerospace, defense, automotive, communications, consumer electronics, energy and healthcare industries. Our antenna team has been using FEKO since 2. Our experience with the software is so positive that we added FEKO to our company strategic tool list. Julie Huffman. Lockheed Martin Space Systems, USAAntenna Design and Placement. FEKO is widely used in the industry for the analysis and design of antennas for industries such as, radio and TV broadcasting, wireless, cellular and communication systems, remote keyless entry systems, tire pressure monitoring systems, satellite positioning and communications, radars, RFID and many others. FEKOs Method of Moments Mo. M solver is used for antenna design but also antennas like reflector antennas, antennas for radars, and antennas with radomes they can all be very efficiently analyzed with FEKO thanks to model decomposition where equivalent sources are generated and used together with accelerated full wave methods like Multi level Fast Multipole Method MLFMM, or asymptotic methods like Physical Optics PO, Ray Launching Geometrical Optics RL GO or Uniform Theory of Diffraction UTD. Antenna arrays can be also very accurately and efficiently analyzed with FEKO, thanks to features like its Domain Greens Functions Method DGFM method for large and finite arrays. Currents at 1. 5 GHz on a 2x. Many techniques exist for the simulation of antennas in free space. In practice, such antennas are mounted on physical structures, which significantly influence their free space radiation characteristics. Measurements of the radiation characteristics of an antenna mounted on a large platform are difficult, or even impossible to perform. Therefore, the challenge exists to accurately simulate, the interaction of an antenna with electrically large environments. Over years, FEKO has gained a lot of reputation for antenna placement becoming the standard EM simulation tool for placement of antennas on vehicles, aircraft, satellites, ships, cellular base stations, towers, buildings and others. MLFMM and the asymptotic solvers in FEKO PO, RL GO and UTD, together with model decomposition, make FEKO the ideal tool to solve antenna placement and co site interference problems on electrically large or very large platforms. Antenna placement on fighter aircraft and ship surface currents are shownRegarding matching circuit design, Optenni Lab, developed by Optenni Ltd. Altair sales channels, provides fully automatic matching circuit generation and optimization routines. The user only needs to specify the desired frequency range and number of components in the matching circuit after which Optenni Lab provides a choice of optimized matching circuit topologies. Optenni Lab uses accurate inductor and capacitor models from major component manufacturers and a fast tolerance analysis to ensure that the manufactured matching circuits will meet the design criteria, making it an ideal tool to complement FEKO. For customers interested in Antenna Magus, antenna synthesis tool from Magus Pty Ltd, it is also available through Altair sales channels. It offers a huge searchable collection of antennas, which can be explored to find and design antennas to user specification. Ready to run FEKO models can be exported, which makes Antenna Magus a tool to complement FEKO. Electromagnetic Compatibility. Electromagnetic Compatibility EMC has become a key and sensitive topic for OEMs and their suppliers in many industries. It is not only important to ensure electromagnetic problems will not occur when integrating components and devices in a system, but also to fulfil the related EMC regulations. Since many years ago FEKO and Flux are used for EMC to simulate problems related to Electromagnetic Interferences EMI and Electromagnetic Susceptibility or Immunity EMS. FEKO includes a complete cable modelling tool to analyze both radiation and irradiation of cables into or from other cables, antennas or devices, which can cause disturbance voltages and currents resulting in malfunctioning the system. FEKO is also used to simulate radiated emissions of Electronic Control Units ECU in a system, shielding effectiveness, radiation hazard analysis, electromagnetic pulses EMP, lightning effects and High Intensity Radiated Fields HIRF. On the other hand, Flux is able to evaluate the magnetic field radiated by power cables and busbars. The effect of external fields on the operation of electromagnetic devices such as sensors or actuators can be determined. It also allows designing efficient shielding. Cable modelling interface in FEKO left and radiated magnetic field study for a power electronic application with Flux rightScattering and RCS. The scattering properties of an object are related to the spatial distribution of scattered energy when the object is exposed to incident electromagnetic fields. Two typical scenarios where scattering is important are the design of systems to detect objects, like collision detection systems, and the design of objects so to increase or decrease its detectability by a transmitter, like a stealth aircraft. The variety of numerical methods in FEKO, including MLFMM, RL GO and PO, together with its post processing capabilities, permits to solve scattering and Radar Cross Section RCS problems very efficiently and accurately. Dvd Player For Windows 10 Free Download. RCS intensity view of a helicopter. RF Devices and Bio Electromagnetics. Waveguides have been widely used since the first space communications in the defense, aerospace, marine and communications industries, for components like couplers, filters, circulators, isolators, amplifiers and attenuators. FEKO is used to simulate waveguide components, where waveguide port excitations and FEKOs Mo. M and Finite Element Method FEM solvers are typically used. Microstrip technology is used to design planar circuits, like couplers, resonators and filters. When circuit trace lengths become comparable to the wavelength, full wave 3. D EM analysis is used. The Planar layered Greens function and the Surface Equivalent Principle SEP formulation in FEKO are very well suited to analyze printed microwave circuits. Horizontal and vertical planes with field direction vectors for a waveguide Delta driven WR 9. T coupler. EM simulation plays a relevant role in the development of biomedical technologies, where simulation offers valuable insight into the interactions of electromagnetic fields inside or in the close proximity to the body. Due to the lossy nature of biological tissue, transmitter design typically focuses on ensuring that sufficient signal is radiated and not lost in the anatomical load, while complying with regulations that limit the specific absorption rate SAR and the maximum thermal increase in the body. Typical applications are related to mobile and wireless devices, RF fields inside automobiles, hearing aids, body worn antennas, MRI, implants, hypothermia, and others. FEM, Finite Difference Time Domain FDTD and Mo. MFEM methods in FEKO are very suitable for these applications. FEKO includes a database of different human body models.