ミューテック List of Products and Services

"μ-Excel" is a low-cost thermal, structural, and electromagnetic field analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for genuine simulations with a familiar user experience. You can check the operation experience through videos for each work step! The video available here is "Step 0: Introduction" - taking the "Magnetic Torque Version" of the "μ-Excel" series as an example, we will introduce its features that gently guide you through 2D axisymmetric analysis using the finite element method via Excel macros. ▽▼▽ Please also check out other videos! ▼▽▼ ▼ Step 0: Introduction Step 1: Starting Excel Step 2: Model Creation Step 3: DXF Import Step 4: Mesh Creation Step 5: Execute Calculation Step 6: Add Materials Step 7: Display Results Step 8: Create Graphs Step 9: Save with Name Step 10: Surface Flux Calculation Step 11: Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis from customized input and output screens tailored to each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation without discomfort using familiar Excel. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Calculation of electromagnetic force and torque for notable magnetic materials - Magnetic field distribution and magnetic line output - DC excitation using magnets and coils - Nonlinearity and magnetic saturation of magnetic materials - Variable position of the plunger * It can be introduced at a lower cost compared to other analysis software. The academic version is even more economical! * For more details, please contact us or download the PDF.

• simulator

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis from customized input and output screens tailored to each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation in a familiar Excel environment without discomfort. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Analysis of current flow in conductive materials - Calculation of electric field, potential distribution, and current vectors - Setting of conductivity and electrode potentials *It can be implemented at a lower cost compared to other analysis software. The academic version is even more advantageous! *For more details, please request materials or view the PDF data from the download.

• simulator

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis through customized input and output screens for each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation in a familiar Excel environment without discomfort. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Electrostatic field analysis, stress distribution analysis - Calculation of electric field, potential distribution, electric field vector, and stress vector - Setting of relative permittivity for composite dielectrics and potential for electrodes *It can be introduced at a lower cost compared to other analysis software. The academic version is even more economical! *For more details, please request materials or view the PDF data from the download section.

• simulator

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step3 DXF Import." - Taking the "Magnetization Torque Version" of the "μ-Excel" series as an example, we will introduce how you can import DXF files drawn in CAD, making model creation more efficient. - ▽▼▽ Please also check out other videos! ▼▽▼ Step0 Introduction Step1 Starting Excel Step2 Model Creation ▼Step3 DXF Import Step4 Mesh Creation Step5 Execute Calculation Step6 Add Materials Step7 Display Results Step8 Create Graphs Step9 Save with Name Step10 Surface Flux Calculation Step11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis through customized input and output screens for each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation in a familiar Excel environment without any discomfort. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Calculation of spatial magnetic fields and fields within magnetic materials - Output of magnetic field distribution, magnetic field lines, and magnetic field vectors - DC excitation using magnets and coils - Nonlinearity and magnetic saturation of magnetic materials *It can be introduced at a lower cost compared to other analysis software. The academic version is even more economical! *For more details, please contact us or download the PDF.

• simulator

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 1 Starting Excel." Using the "Magnetic Torque Version" of the "μ-Excel" series as an example, we will demonstrate the analysis based on a macro-enabled workbook prepared for each analysis theme, showing that all input data and result information fit on the sheets. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction ▼Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis from customized input and output screens tailored to each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation in a familiar Excel environment without discomfort. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that fits your theme (currently, there are a total of 11 series). 【Features】 - Analysis of electric fields and magnetic fields, and behavior analysis of ion beams in electric and magnetic fields - Start trajectory calculations with the mass, charge number, initial coordinates, and initial velocity of charged particles - Calculation of electric fields, potential distributions, magnetic fields, magnetic field lines, and trajectory diagrams - Repulsive forces applied to multiple charged particles *Compared to other analysis software, it can be introduced at a lower cost. The academic version is even more advantageous! *For more details, please contact us or download the PDF.

• simulator

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 7 Result Display" - taking the "Magnetic Torque Version" of the "μ-Excel" series as an example, we will introduce the display of vector diagrams, contour maps, and magnetic flux lines, as well as the ability to create documents using cut and paste. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials ▼Step 7 Result Display Step 8 Create Graphs Step 9 Save As Step 10 Surface Magnetic Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the operation experience through videos for each work step! The video available here is "Step 2 Model Creation" - taking the "Magnetic Torque Version" of the "μ-Excel" series as an example, we will introduce the steps to build a model using the included modeler with points, lines, and surfaces. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel ▼Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis through customized input and output screens for each theme. Additionally, it utilizes Excel macros in the GUI, enabling users to operate it seamlessly with familiar Excel. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - High-frequency eddy current analysis of heating coils - Unsteady temperature analysis - Temperature, heat generation, magnetic field distribution, magnetic field lines - Transmission boundaries, radiation boundaries, material temperature dependence, nonlinearity of magnetic materials - Impedance calculation, resonant circuit design * It can be introduced at a lower price compared to other analysis software. The academic version is even more economical! * For more details, please contact us or download the PDF.

• simulator

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 5: Execute Calculation" - taking the "Magnetic Torque Version" of the "μ-Excel" series as an example, it easily sets calculation conditions with macros for each theme, and introduces that the protected USB key is only needed during calculations. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation ▼Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for genuine simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 4: Mesh Creation." - Taking the "Magnetization Torque Version" of the "μ-Excel" series as an example, we will introduce the auto-mesh function, specification of mesh density, and periodic boundary condition functions during motor analysis. - ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import ▼Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 9: Save As" - taking the "Magnetic Torque Version" of the "μ-Excel" series as an example, by saving with a name such as the date, all input and output data can be completed in a single Excel file, making data organization easy. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs ▼Step 9 Save As Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 8: Graph Creation." Using the "Magnetic Torque Version" of the "μ-Excel" series as an example, we will introduce the feature that stores result values at arbitrary coordinates in cells, enabling Excel's inherent spreadsheet and graph functions. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results ▼Step 8 Graph Creation Step 9 Save with Name Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the operation experience through videos for each work step! The video available here is "Step 10 Surface Magnetic Flux Calculation" - taking the "Magnetization Torque Version" of the "μ-Excel" series as an example, we will introduce the flow of surface magnetic flux evaluation created by the magnetized magnets unique to the magnetization torque version. ▽▼▽ Please be sure to check out other videos as well! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As ▼Step 10 Surface Magnetic Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 11 Torque Calculation" - taking the "Magnetization Torque Version" of the "μ-Excel" series as an example, we will introduce the torque calculation after incorporating magnets magnetized into the motor, which is unique to the magnetization torque version (further expanding into motor characteristic analysis). ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation Step 6 Add Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As Step 10 Surface Magnetic Flux Calculation ▼Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

"μ-Excel" is a low-cost thermal, structural, and electromagnetic analysis software that overturns the common belief that analysis software is expensive. It operates on Excel, allowing for professional simulations with a familiar user experience. You can check the user experience through videos for each work step! The video available here is "Step 6: Adding Materials" - taking the "Magnetic Torque Version" of the "μ-Excel" series as an example, we will introduce how to add the BH curve for magnetic materials to the material sheet and freely reference the material database. ▽▼▽ Please also check out other videos! ▼▽▼ Step 0 Introduction Step 1 Starting Excel Step 2 Model Creation Step 3 DXF Import Step 4 Mesh Creation Step 5 Execute Calculation ▼Step 6 Adding Materials Step 7 Display Results Step 8 Create Graphs Step 9 Save As Step 10 Surface Flux Calculation Step 11 Torque Calculation

• Magnetic field analysis/electromagnetic wave analysis

This is an introduction to the next-generation iron loss evaluation method, the "E&S Model." Based on an evaluation method called vector magnetic characteristics, it has become possible to obtain a more detailed analysis of the loss distribution in steel materials compared to conventional methods. It can calculate high-precision magnetic fields, magnetic flux densities, and iron loss distributions that are not achievable with other software. 【Features】 - By considering vector magnetic characteristics, magnetic vectors can be calculated with high precision. - It can compute rotating magnetic fields and hysteresis. - It is designed as an easy-to-use tool specifically for iron loss evaluation. - It includes permanent magnet excitation functionality and torque calculation functionality. *For more details, please contact us or download the PDF.

• Magnetic field analysis/electromagnetic wave analysis

Iron loss evaluation, which has been a bottleneck in motor analysis. Conventional methods only consider iron loss as a function of magnetic flux density, resulting in low accuracy. However, accurately determining the magnetic field and magnetic flux density to calculate iron loss is achieved through "vector magnetic characteristic analysis." This allows for the calculation of high-precision distributions of magnetic fields, magnetic flux densities, and iron losses that are not achievable with other software. Vector magnetic characteristics refer to the properties that take into account the relationship between the magnetic field H and magnetic flux density B of electromagnetic steel materials, considering their direction (vector). The finite element method electromagnetic field simulator that incorporates this characteristic is “μ-E&S.” 【Features】 - High-precision calculation of magnetic field vectors is possible by considering vector magnetic characteristics. - Rotating magnetic fields and hysteresis can be calculated. - It is designed as an easy-to-use tool specifically for iron loss evaluation. *For more details, please request materials or view the PDF data available for download.

• Magnetic field analysis/electromagnetic wave analysis

This document presents a basic analysis example aimed at the iron loss distribution of SPM (Surface Permanent Magnet) motors. It provides a detailed explanation of the analysis model and objectives, as well as the magnetic flux lines, magnetic field distribution, and iron loss distribution results. [Contents] ■4.1 Analysis Model and Objectives ■4.2 Analysis Conditions and Calculation Time ■4.3 Magnetic Flux Lines, Magnetic Field Distribution, Iron Loss Distribution Results ■4.4 Results of Inclination Angle θB and Aspect Ratio α Distribution ■4.5 X-Direction Hysteresis Curve Results ■4.6 Y-Direction Hysteresis Curve Results ■4.7 Lissajous Waveform Results ■4.8 Current Waveform Results *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

AirCube is a pre-post system specifically designed for orthogonal grids that supports the finite difference method, widely used in fluid analysis, electromagnetic wave analysis, and sound field analysis. It can be easily linked to your solver. Compared to conventional software, it is simple, user-friendly, and multifunctional, capable of meeting various needs. Additionally, it demonstrates high performance even with large-scale models and can accommodate complex shapes. 【Pre-Processing Features】 - Boundary condition support such as PML - CAD input - Shape library including cylinders and rectangular prisms - High-speed automatic cell division - Solver control for time steps and output steps 【Post-Processing Features】 - Cut surface contours - Graphs - Point extraction plots - Full model generation from half models - Automatic processing via session files - Animation features *For more details, please request documentation or view the PDF data available for download.

• Other analyses

This document presents an analysis example aimed at comparing the magnetic field and iron loss distribution of IPM (Interior Permanent Magnet) motors using vector magnetic characteristic analysis and conventional method analysis. It provides a detailed explanation of the analysis model and objectives, as well as the results of magnetic flux lines, magnetic field distribution, and iron loss distribution. 【Contents】 ■5.1 Analysis Model and Objectives ■5.2 Analysis Conditions and Calculation Time ■5.3 Magnetic Flux Lines, Magnetic Field Distribution, Iron Loss Distribution Results ■5.4 Comparison with Conventional Methods ■5.5 Results of Angle θB and Aspect Ratio α Distribution ■5.6 Hysteresis Curve and Lissajous Waveform Results *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis through customized input and output screens for each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation in a familiar Excel environment without discomfort. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Magnetic analysis of magnetizer models - Calculation of magnetization distribution, magnetization direction, and surface magnetic flux - Torque analysis of motor models - Automatic transfer of magnetization information and rotor rotation function - Calculation of rotation angle vs. torque curve - Improvement of meshing algorithms (examples are shown in the photos below) *It can be introduced at a lower cost compared to other analysis software. The academic version is even more advantageous! *For more details, please contact us or download the PDF.

• simulator

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. It consists of individual packages for each analysis theme, allowing for smooth analysis through customized input and output screens for each theme. Additionally, it utilizes Excel macros in the GUI, enabling operation in a familiar Excel environment without discomfort. Furthermore, it can be introduced at a lower cost compared to other analysis software. The academic version is even more economical! It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Designed for cooling circuit design of press parts using molds - Settings for the initial temperature of press parts, the position, number, and heat absorption of cooling pipes on the mold side - Calculation of transient temperatures during the cooling process after pressing and the repeated insertion of new press parts - Ability to set the heat transfer coefficient based on pressing pressure - Display of temperature changes *For more details, please contact us or download the PDF.

• simulator

This document presents an analysis example using a transformer model with directional materials. It provides a detailed explanation of the analysis model and objectives, as well as the results of magnetic flux lines, magnetic field distribution, and iron loss distribution. [Contents] ■3.1 Analysis Model and Objectives ■3.2 Analysis Conditions and Calculation Time ■3.3 Results of Magnetic Flux Lines, Magnetic Field Distribution, and Iron Loss Distribution ■3.4 Results of Angle θB and Aspect Ratio α Distribution ■3.5 Results of Hysteresis Curve in the X Direction ■3.6 Results of Hysteresis Curve in the Y Direction ■3.7 Results of Lissajous Waveform ■3.9 Results of Current Waveform *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

This document presents an analysis example using a model of isotropic electromagnetic steel plates shaped into a ring. It provides a detailed explanation of the ring model voltage source, as well as comparison results with measured values of the hysteresis curve. 【Contents】 ■1.1 Analysis Model and Objectives ■1.2 Analysis Conditions and Calculation Time ■1.3 Magnetic Field Distribution and Iron Loss Distribution Results ■1.4 Alternating Magnetic Flux and Rotating Magnetic Field Results ■1.5 Comparison Results with Measured Values of the Hysteresis Curve ■1.6 Current Waveform Results ■1.7 Interface Settings Screen *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

μ-Excel is analysis software that uses a two-dimensional (or axisymmetric) finite element method. The μ-Excel series consists of individual packages for each analysis theme, allowing for smooth analysis through customized input and output screens for each theme. Additionally, it utilizes Excel macros in the GUI, enabling users to operate it seamlessly with familiar Excel. It is evolving into a rich variety of themes, not only for electromagnetic field analysis but also for heat, structure, fluid, and electromagnetic waves. Please look for the series that matches your theme (currently, there are a total of 11 series). 【Features】 - Dedicated package for architecture and construction companies - Selection of MRI coils for 1.5T and 3T - Only requires setting the room outline and the number of shielding materials - With just one calculation button, it goes from meshing to calculation to result display - Displays 5 Gauss lines *It can be introduced at a lower price compared to other analysis software. The academic version is even more affordable! *For more details, please request materials or view the PDF data from the download.

• simulator

This document presents an analysis example using a model of isotropic electromagnetic steel sheets shaped into a ring. It provides detailed explanations on various topics, including the ring model voltage source (differences in steel materials), magnetic field distribution, and iron loss distribution results. [Contents] ■2.1 Analysis Model and Objectives ■2.2 Analysis Conditions and Calculation Time ■2.3 Magnetic Field Distribution and Iron Loss Distribution Results ■2.4 X-Direction Hysteresis Curve Results ■2.5 Y-Direction Hysteresis Curve Results ■2.6 Current Waveform Results *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

μ-Beam is a three-dimensional trajectory analysis module for charged particles that takes into account space charge. It can simulate ion beam control. μ-Beam is the trajectory analysis module within the electromagnetic field analysis system μ-MF by Mutech. 【Features】 - Trajectory analysis of charged particles in electric and magnetic fields - Input functions for initial position, initial velocity, and assigned current of charged particles - Function to read condition setting CSV files from Excel - Specification of calculation range and automatic calculation stop function - Trajectory analysis considering classical and relativistic effects - The trajectory calculation method employs Runge-Kutta *For more details, please request documentation or view the PDF data available for download.

• Electron beam lithography equipment

The optical wave and microwave analysis software μ-WAVE is a highly practical electromagnetic wave simulation tool. μ-WAVE quickly analyzes the electromagnetic field distribution in the time domain. 【Features】 - Adopts FDTD and CIP methods for analysis - High-speed computation for problems on the scale of 10 million cells (when using FDTD) - Realizes infinite boundaries without PML (when using CIP) - The time step determined by the Courant condition remains unchanged even with partially small cells (significantly reduces computation time) (CIP) - Evaluates wideband absorption and scattering characteristics in a single calculation - Comes standard with a dedicated GUI designed for ease of use - Priced from 3.15 million yen *For details, please request materials or view the PDF data available for download.

• Magnetic field analysis/electromagnetic wave analysis

μ-COOL is a temperature simulation software that calculates temperature effects on Excel. By simply inputting painting conditions and indoor sizes, it can calculate the temperature effects before and after painting on the spot. It serves as a powerful persuasive tool during negotiations with clients. ■Features - Uses Excel macros - Utilizes NEDO's solar radiation database - Allows setting the size of facilities (factories), etc. - Calculates indoor temperature changes over 10 days - Computes temperature reduction effects with and without heat-reflective paint - Customizable *For more details* If you have any questions or concerns, please feel free to contact us!

• Thermometer

This document explains the vector magnetic characteristic analysis technology for achieving high-efficiency motors. This technology is supported by Professor Masato Enokizono (Emeritus Professor at Oita University, currently the representative of the Vector Magnetic Characteristic Technology Research Institute), and we have cited information from the Vector Magnetic Characteristic Technology Research Institute, which is headed by the professor. [Contents] 1. The target is the reduction of iron loss in electromagnetic steel sheets. 2. Iron loss is the sum of eddy current loss and hysteresis loss. 3. Vector magnetic characteristics of electromagnetic steel sheets. 4. Conventional measurements are scalar magnetic measurements. 5. Developed vector magnetic measurements. 6. Actual measurement results. 7. Database creation as magnetic characteristics. *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

This document is a technical column edited and compiled based on the content related to "Vector Magnetic Characteristic Analysis" mentioned in past newsletter columns. We would like to disseminate information about the importance of vector magnetic characteristic analysis technology for achieving high-efficiency motors. [Contents] ■1. Vector Magnetic Characteristic Analysis Technology - Prologue - ■2. Top Runner Method and IE4 ■3. Inverter Technology and Energy Saving ■4. Will Increasing Size Lead to IE3? ■5. Electrical Steel Sheets are Excellent ■6. Focus on the Vector Magnetic Characteristics of Electrical Steel Sheets *For more details, please refer to the PDF document or feel free to contact us.

• PM motor

Ion beam device design software. Limited to axisymmetric models, but allows for easy evaluation of results using Excel macros. Calculates electric field distribution, magnetic field distribution, and trajectory distribution. Can take into account space charge effects.

• others

It is ideal for the design and manufacturing sites of high-frequency heating, quenching, and annealing.

• Magnetic field analysis/electromagnetic wave analysis
• Other metal materials
• others

The electrostatic current version calculates the current density within the conductor and the resistance between the electrodes. It addresses a variety of themes such as thermistors, heating wires, printed circuit boards, and sensor electrodes. For more details, please refer to the "Introduction to 163 ex Electrostatic Current Version" on 【Analysis Know-How.com】. Key points are as follows: - The electrostatic current version checks the current distribution within the conductor. - It is a simple analysis, but there are various themes. - For thermistors, it examines the current density between the electrodes. - For heating wires in rear glass, it investigates how to ensure an even current flow. - For printed circuit boards, it estimates heat generation from the current density in the wiring. - For sensor electrodes, it estimates the material of the lower layer based on resistance values.

• simulator

The electrostatic current version calculates the current density within conductors and the resistance between electrodes. It addresses a variety of themes such as thermistors, heating wires, printed circuit boards, and sensor electrodes. For more details, please refer to "163 ex Electrostatic Current Version Introduction" on 【Analysis Know-How.com】. Key points are as follows: - The electrostatic current version checks the current distribution within conductors. - It is a simple analysis, but there are various themes. - For thermistors, it examines the current density between electrodes. - For heating wires in rear glass, it investigates how to ensure an even current flow. - For printed circuit boards, it estimates heat generation from the current density in the wiring. - For sensor electrodes, it estimates the material of the lower layer based on resistance values.

• Other analyses

Would you like to conduct a simulation yourself to check if the 5GAUSS line leaks from the room? We have developed software that is easy to operate, even for construction design personnel who are not familiar with analysis. By setting the room layout and the number of shields, you can simply press the execute button to output the 5GAUSS line drawing. By performing repeated calculations, you can consider the optimal shield placement and the minimum number of shields needed. For more details, please visit [Analysis Know-How.com] and see "062 Introduction to μ-MRI." Here are the key points: - Dedicated software for MRI shield rooms - Specification of room layout and the number of shields for walls and floors - One-button operation for mesh division and calculation execution - Direct display of the 5GAUSS line - Complex analyses made accessible to anyone Additionally: - We offer professional consulting that addresses your specific issues - We provide contracted analysis and custom development at a low cost.

• Other analyses

As a result of processing, the values of arbitrary coordinates are stored in cells, and graphs can also be displayed. For details, please refer to "NO.022 Evaluation Points and Graph Display" on 【Analysis Know-How.com】. Key points are as follows: - Results of arbitrary evaluation point coordinates are stored in cells on the evaluation sheet. - These results are displayed in graphs. - Excel calculations can be freely performed. - Calculation results are interpolated at arbitrary coordinates for each node and element.

• Other analyses

You can export existing model information to a file, import it for other analysis themes, and immediately use it for analysis. For details, please refer to "NO.138 Importing Model Information" on 【Analysis Know-How.com】. Here are the key points: - Model information can be exchanged via files. - Export model information. - Import model information. - Save model information and use it for analysis of other themes.

• Other analyses

Contour lines represent size with color, while vectors represent direction with arrows. For details, please refer to "NO.021 Contour Lines and Vector Representation" on 【Analysis Know-How.com】. Key points are as follows: - Contour lines are also referred to as contour displays. - Temperature distribution and magnetic field strength are represented with color. - Vectors refer to arrows. - The direction of the magnetic field and the flow of heat are represented by the direction of the arrows. - The color and length of the arrows also have significance. - Additionally, there are representations using lines such as magnetic flux lines and equipotential lines.

• simulator

In the electrostatic current version, we calculate the current distribution flowing through the conductor between the electrodes. From the current distribution, we can derive the amount of heat generated, and at the same time, we can also calculate the resistance value R between the electrodes. Once the resistance R is obtained, it can be used for circuit calculations, etc. For more details, please refer to "NO.162 Can the resistance value be determined?" on 【Analysis Know-How.com】. Key points are as follows: - We want to determine the resistance R between electrodes with a complex structure. - It can be calculated from the heat loss energy of the current flowing through the conductor. - In the electrostatic current version, R is calculated from the heat energy. - In a two-dimensional model, the depth dimension is specified for calculation. - If R is determined, it can be used for circuit calculations.

• Other analyses

Impedance has frequency characteristics. In an equivalent circuit, it can be represented as a parallel circuit of the resistance R and the capacitance C. In an alternating current field, when the frequency is low, current flows through the R part, and as the frequency increases, current flows through the C part. For more details, please refer to "NO.161 Frequency Characteristics of Impedance" on [Analysis Know-How.com]. Here are the key points: - Impedance has frequency characteristics. - Resistance R can be derived from conductivity σ. - Reactance X = 1/ωC can be derived from permittivity ε. - Z (impedance) is given by Z = RX / (R + X). - C can be calculated from the electrostatic field version. - R can be calculated from the electrostatic current version.

• Other analyses

We calculate the magnetic field shielding effect due to eddy currents, as well as the distribution of eddy currents, heat generation distribution, and the amount of heat generated. When defined as multiple conductors, the eddy currents in each conductor can be calculated in a closed state. For more details, please refer to "NO.049 ex Eddy Current Number Introduction" on 【Analysis Know-How.com】. Here are the key points: - Input the frequency of the excitation coil, as well as the permeability and conductivity of the materials. - Eddy currents are closed within the conductors. - It can be defined as multiple conductors. - As a result, eddy currents flow in each conductor, reducing losses. - Displays the magnetic field, eddy current, and heat generation distribution. - Outputs the total amount of heat generated (loss amount).

• Other analyses