2D & 3D Magnetic Field Simulation Modeling
- 3d Magnetic Field Simulation Software
- Magnetic Force Simulator
- 3d Magnetic Field Simulation Matlab
- Free Magnetic Field Simulator
- Free Magnetic Simulator
State-of-the-art Risk Mitigation Technology
3d Magnetic Field Simulation Software
OPhysics: Interactive Physics Simulations. This is a 3D simulation of a charged particle moving in a magnetic field. Adjust the strength of the magnetic field, the particle mass, particle charge, and its initial velocity in the x and z directions using the sliders. Hit the RUN button to observe the path of the particle in the magnetic field. EMS is a 3D electromagnetic field simulator software suite, based on the powerful finite element method. Currently, it is the only electromagnetic Add-in available to SOLIDWORKS users. EMS is Gold Certified by SolidWorks® and targets four main areas: electromechanical, electromagnetic, power electronics, and electromagnetic behavior.
![3d Magnetic Field Simulator Free 3d Magnetic Field Simulator Free](/uploads/1/3/8/2/138246902/115511771.jpg)
We provide plan-view and elevation view magnetic field simulation modeling of building electrical systems: Simulation modeling at a 50% and 75% building loads. These EMF simulation models illustrate the magnetic emissions profile as a 2D horizontal or vertical plane through the building. The sophisticated computer model calculates the magnetic emissions profiles as a function of magnitude and distance from the numerous electrical sources.
The computer generated building EMF simulation models can incorporate elements such as: transformers, switchboards, panels, feeders, automatic transfer switches (ATS) and more.
Magnetic Force Simulator
Source Modeling
Source modeling shows individual electrical elements and the potential impact on nearby sensitive EMI instrumentation and equipment. This type of computer modeling can assist in the placement for future equipment to optimize the use of building space and reduce the need for magnetic mitigation.
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Electrified 50/60 Hz AC and 600 VDC Traction Current Simulation Modeling
Simulated future underground train and subway commuter tunnels can impact adjacent buildings with EMI sensitive instrumentation. The figure below shows a 25-0-25 kVA traction current underground catenary rail system emission profile.
The auto-transformer style traction system creates certain mitigation design challenges. The computer generated emission profile from the railway can be utilized to provide guidance to developers for placement of the railway to not only reduce electromagnetic interference for sensitive imaging equipment but also for human health purposes.
Electrified DC Third-Rail System
In addition to alternative current (AC) traction systems Vitatech also provides magnetic field simulation modeling of direct current (DC) traction systems. The figure below shows an elevated third-rail 600 VDC electrified train adjacent to a medical research building.
DC traction systems are typical in urbanized environments.
The MLX90395 is a 3D magnetometer capable of measuring X, Y, and Z magnetic fields and is an expansion of the set of Melexis sensors offering this output. Unlike many other magnetometers, the MLX90395 is designed to sense magnetic fields produced by a permanent magnet versus earths magnetic field. Therefore, the MLX90395 is well suited to sense the position of a static or moving magnet in the vicinity of the sensor by measuring the magnetic fields produced by it.
Compared to the previously released, consumer-product-focused MLX90393, the MLX90395 shares many features but also differs in many ways.
3d Magnetic Field Simulation Matlab
Wider temperature range
The MLX90395 operates over a wider temperature range than the MLX90393, from -40 degC to 125 degC ambient, making the MLX90395 suitable for in-cabin, on-body, or light powertrain applications in automotive. It is also suitable for many industrial applications like factory automation, robotics, or material handling.
The MLX90395 operates over a wider temperature range than the MLX90393, from -40 degC to 125 degC ambient, making the MLX90395 suitable for in-cabin, on-body, or light powertrain applications in automotive. It is also suitable for many industrial applications like factory automation, robotics, or material handling.
Higher speed operation
The speed has been increased, up to a 2kHz peak sampling rate, when measuring all three magnetic field axes.
The speed has been increased, up to a 2kHz peak sampling rate, when measuring all three magnetic field axes.
Supply voltage measurement
The MLX90395 can also measure its own supply voltage to enable a plausibility check to be conducted with the ADC in the host microcontroller. The supply voltage measurement also enables monitoring of battery discharge in battery powered applications.
The MLX90395 can also measure its own supply voltage to enable a plausibility check to be conducted with the ADC in the host microcontroller. The supply voltage measurement also enables monitoring of battery discharge in battery powered applications.
Two ranges of field
The MLX90395 provides two magnetic field versions; a medium field and a high field version. The medium field version enables 50mT maximum magnetic field in the X and Y axes and 130mT in the Z axis. The high field variant extends the magnetic field range to 120mT in the X and Y axes with the same 130mT maximum field in the Z axis.The high field version is particularly suited for applications where stray magnetic fields, produced by another magnet or by a current carrying conductor, may be present. By increasing the desired signal from the permanent magnet the error due to the infringing field will be reduced.For both versions, exceeding the maximum field range will not damage the sensor. Returning within the operating conditions will return the sensor to normal operation.
The MLX90395 provides two magnetic field versions; a medium field and a high field version. The medium field version enables 50mT maximum magnetic field in the X and Y axes and 130mT in the Z axis. The high field variant extends the magnetic field range to 120mT in the X and Y axes with the same 130mT maximum field in the Z axis.The high field version is particularly suited for applications where stray magnetic fields, produced by another magnet or by a current carrying conductor, may be present. By increasing the desired signal from the permanent magnet the error due to the infringing field will be reduced.For both versions, exceeding the maximum field range will not damage the sensor. Returning within the operating conditions will return the sensor to normal operation.
Automotive qualification and multi-packages
Finally, the MLX90395 is automotive qualified to the AEC Q100 standard and is available in a RoHS compliant 3x3mm QFN16, SOIC8, or TSSOP16 package. The QFN16 and SOIC8 packages contain a single silicon die while the TSSOP16 contains two fully independent dies for applications requiring redundancy for safety or availability reasons.
Finally, the MLX90395 is automotive qualified to the AEC Q100 standard and is available in a RoHS compliant 3x3mm QFN16, SOIC8, or TSSOP16 package. The QFN16 and SOIC8 packages contain a single silicon die while the TSSOP16 contains two fully independent dies for applications requiring redundancy for safety or availability reasons.
Free Magnetic Field Simulator
Protocol
The MLX90395's output is selectable between SPI or I2C allowing flexibility in integration. The SPI protocol operates at a clock speed up to 10 megahertz while the I2C protocol supports I2C standard mode with clock rates up to 100 kilohertz or I2C fast mode with clock rates up to 1 megahertz. Trigger and interrupt pins are provided for starting measurements at defined times and flagging when data is ready. Triggering via command and polling are also supported for pin-count constrained applications.
The MLX90395's output is selectable between SPI or I2C allowing flexibility in integration. The SPI protocol operates at a clock speed up to 10 megahertz while the I2C protocol supports I2C standard mode with clock rates up to 100 kilohertz or I2C fast mode with clock rates up to 1 megahertz. Trigger and interrupt pins are provided for starting measurements at defined times and flagging when data is ready. Triggering via command and polling are also supported for pin-count constrained applications.
Free Magnetic Simulator
Flexibility
The MLX90395 is highly configurable. For example, the axes to be converted can be chosen from any combination of X, Y, and Z. For example, in many rotary motion applications only X and Y magnetic fields need to be sensed. The Z axis can therefore be skipped saving current and time. The supply voltage and temperature measurements are similarly selectable.
The MLX90395 is highly configurable. For example, the axes to be converted can be chosen from any combination of X, Y, and Z. For example, in many rotary motion applications only X and Y magnetic fields need to be sensed. The Z axis can therefore be skipped saving current and time. The supply voltage and temperature measurements are similarly selectable.