XF enables in-depth analysis of high-frequency array antennas and complex devices operating at millimeter wave frequencies. Leveraging the electromagnetic principle of superposition, XF can quickly analyze hundreds or thousands of port phase combinations when determining beam states for a 5G-enabled device design. By combining steady-state results from the simulation, XF efficiently determines the port phases that maximize the far zone coverage in each direction. In addition, XF computes S-Parameters, efficiencies and far field for each of the elements in a device and generates a CDF of EIRP plot to provide a total performance metric of one or more of the arrays in a device.
Learn more about XF’s features for 5G Array Analysis...
XF improves chip component and matching network analysis using a combined time-domain circuit solver and full wave electromagnetic solver. Import the schematic for a desired component via a netlist file, including SPICE elements such as resistors, capacitors, inductors, coupled inductors, and subcircuits.
Netlist components can also be assigned as a matching circuit embedded within a feed, further simplifying matching network design. Two-, three-, and four-port matching
networks can be defined as a SPICE model and included
in a voltage source within XF. This saves users from defining
each element in the matching network as an individual circuit
Learn more about XF's Circuit Co-Simulation...
Wrap for Flexible Circuits
Wrapping is essential for simulating flexible PCBs because leading layout tools produce a flat design. Without efficient simulation software, manually adding multiple bends is a painstakingly slow process. To replicate the physical model, XF’s wrapping capability supports full, multi-layer flexible PCBs during import, eliminating the need to wrap individual layers and parts manually. Simply select the PCB file from
the Import menu, provide the form, and let XF wrap the PCB
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Complying with measurement standards and meeting performance expectations requires versatile antenna design software. By supporting Poseable Hand models, XF simulates cell phone use scenarios for successful device design. The Poseable Hand models offer numerous other orientations to mimic real-world positioning.
Learn more about XF's Poseable Hands feature…
Many configurations need to be tested during the design iteration phase - this is necessary for a thorough antenna analysis - but setting up each configuration manually can be a repetitive and time consuming process. A successful production environment requires automation and a customized workflow to maintain efficiency.
Project setup can be automated to include the following options:
- Include/exclude hands, head, and other parts in the mesh
- Create simulations for main, diversity, GPS, and Bluetooth antennas
- Set the frequency range for different antennas, including the waveform
- Enable output requests and set DFT frequencies
Automation also applies to data export. XF can consolidate data - S-Parameters, impedance, radiation, and system efficiency - from multiple simulations and export it to a spreadsheet.
A mobile device is only as good as its wireless connection, so it is necessary to quantify antenna diversity within the EM simulation. XF considers field polarization and direction when computing complex correlation and mean effective gain outputs. This allows XF users to evaluate the quality and reliability of a device’s antenna system and then improve the design’s performance to capture the strongest wireless link in multipath situations.
Specific Absorption Rate (SAR)
Complying with FCC standards is a requisite part of mobile device design that demands reliable EM simulation software. In addition to single antenna operation, XF has the ability to combine SAR results when there are multiple antennas operating in the same frequency band to get the total 1g and 10g SAR values. This allows engineering to keep power levels below the specified threshold and ensure a device performs within regulations.
Full-Wave Matching Circuit Optimization (FW-MCO)
Determining the layout is only part of the matching circuit design process. Component values must then be selected with consideration to the actual antenna’s properties to ensure the design accepts a signal. Modern matching circuits include traditional RLC and tunable components, which presents a unique challenge when choosing a specific component to place in a matching network.
The FW-MCO method takes the guesswork out of choosing component values by assessing the antenna’s properties and evaluating thousands of
possible component combinations. It selects optimal values based on the
user’s defined goals and thresholds, generating an efficient matching network.
FW-MCO utilizes XF’s Circuit Element Optimizer feature.
XF’s capabilities are the keystone of a comprehensive antenna design process that continues with indoor modeling. Wireless InSite supports XF’s radiation patterns as input and offers full control of defining a wireless environment. The ability to import files, create objects, and edit a floor plan ensures a realistic simulation, and site-specific placement of the transmitter helps to assess the device’s received power.
Learn more about MIMO and Array Design for 5G...