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RF Module simulates everything from waveguides to metamaterials

The pervasive mobile technology of cellular phones is often used in automotive environments. The effect a car's body has on an antenna's electric field becomes an important parameter.

Terahertz waves are an alternative to X-rays without the damaging side effects. Yet they are also more difficult to control, so models are required to aid the development of future waveguides. Model provided courtesy of Dr. Jason Deibel, Rice University, Houston, TX.

One of the great challenges in finite element modeling is how to treat open boundaries in radiation problems. The RF Module offers the use of perfectly matched layers (PMLs) to absorb all wave phenomena.

BURLINGTON, MA (August 16, 2006)-The RF Module for COMSOL Multiphysics enables unique simulation capabilities for the design of today’s sophisticated RF, microwave, and photonics components, and in general the software makes it easier than ever to study components and systems that deal with propagating electromagnetic waves. With it users can design and prototype devices for the transmission, guiding, receiving, and filtering/processing of electromagnetic waves in applications where the range of frequencies spans from radio to optical.

With the module, users can consider all sorts of multiphysics effects including the interconnection of electromagnetics phenomena with heat transfer, structural mechanics, and more. For instance, it is possible to see what effects heating has upon the frequency response of a microwave filter. Users can also see in high-power microwave waveguides or switches how close a design gets to safety margins before electric breakdown of air or a gas occurs. They can then experiment with software on a better physical design or choice of materials to increase safety margins. To make such analyses easier, the module provides a ready-made multiphysics coupling for microwave heating. Here users no longer have to determine which physics they must select to solve this problem and then struggle to decide which boundaries couple them together; the software automates this process with a few mouse clicks.

A key feature in the RF Module is the characterization of S-parameters / reflection-transmission coefficients. For a given geometry and set of physics, users can determine such values over a wide range of frequencies. This S-parameter analysis is ideal for waveguides, antennas, filters, directional couplers, switches, microwave amplifiers, transmission lines, and impedance-matching networks.

Designing Stealth Technology and T-rays Applications

The module also serves to help scientists learn more about a fascinating new field called metamaterials, also known as left-handed or negative-index materials—in which the permeability and permittivity are simultaneously negative. These materials create all sorts of unusual phenomena: They break the diffraction limit to improve resolution in optical devices such as microscopes, they reverse the Doppler effect, and they can create very low reflectance, which is useful in stealth technology. With the RF Module scientists can analyze the frequency-dependent properties of such materials and learn how to build optical or microwave components using them.

An important emerging technology in electromagnetic-wave engineering is the transmission of terahertz rays. These so-called T-rays are well suited for applications such as the detection of explosives or contraband, defect analysis, moisture monitoring, medical diagnostics, trace-gas detection, and biomedical imaging. Comments Dr. Jason Deibel of the Mittleman Terahertz Research Group at Rice University, “COMSOL Multiphysics can be effectively and efficiently used to model engineering problems and phenomena associated with terahertz wave propagation.” Specifically, he successfully used this software to evaluate the design of a radial photoconductive terahertz antenna (for details, see www.comsol.com/stories/terahertz).

A Simulation Head-Start with the RF Model Library

Using these and other features, the RF Module is well suited for a wide range of applications including the design and analysis of:

• Antennas
• Microwave waveguides
• Coplanar waveguides (CPWs) and microstrips
• Cavity filters
• High-power microwave components
• Scattering problems in lasers and optics
• Magneto-optical storage devices
• Dielectric mirrors
• Bragg gratings
• Terahertz waveguides
• Optical waveguides and filters
• Photonic-crystal waveguides

To help users learn how to apply the RF Module to these and other application areas, the software comes with a Model Library with more than 25 real-world examples. One typical example optimizes the design of a microwave filter by accounting for material and geometric shape changes induced by thermal strains; another examines the operation of a microwave oven with heat dissipation in food. Each model has a detailed technical description of the underlying physics along with step-by-step instructions on how to create the model. In this way users not only leverage the knowledge of COMSOL's engineering staff to learn how to apply the software to a particular application, they also can open these models to gain a valuable head-start in their modeling work.

Price and Availability

The RF Module for COMSOL Multiphysics sells for $3495, and it requires COMSOL Multiphysics, which sells for $7995 for a single-user license. Both products are available immediately.

About the COMSOL product line

COMSOL Multiphysics is the first software environment to provide scientists, engineers, and researchers with integrated, best-in-class technology for modeling, simulating, and discovering any system with both single or multiple physics phenomena. A broad range of discipline-specific modules extends the COMSOL environment for chemical engineering, earth science, electromagnetics, heat transfer, MEMS, and structural mechanics applications. COMSOL also offers the COMSOL Reaction Engineering Lab®, which allows users to model reacting systems. COMSOL products are available for the Windows, Linux, Solaris, and the Macintosh operating systems. Full details about COMSOL Multiphysics and related products are available at www.comsol.com.

About COMSOL, Inc.

COMSOL was founded in 1986 in Stockholm, Sweden, and has grown to include offices in the Benelux, Denmark, Finland, France, Germany, Italy, Norway, Switzerland, the United Kingdom, and a US presence with offices in Burlington, MA, Los Angeles, CA, and Palo Alto, CA. Additional information about the company is available at www.comsol.com.

COMSOL, COMSOL Multiphysics, COMSOL Reaction Engineering Lab, and FEMLAB are registered trademarks of COMSOL AB. Other product or brand names are trademarks or registered trademarks of their respective holders.