Last Updated: Aggregation Period:Mar 18, 2026~Apr 14, 2026
This ranking is based on the number of page views on our site.
Last Updated: Aggregation Period:Mar 18, 2026~Apr 14, 2026
This ranking is based on the number of page views on our site.
Last Updated: Aggregation Period:Mar 18, 2026~Apr 14, 2026
This ranking is based on the number of page views on our site.
601~630 item / All 6464 items
Inclusive process simulation
AVEVA PRO/II Simulation is a professional tool that performs comprehensive simulations necessary for process design, improvement, and operational analysis. It calculates rigorous steady-state thermal and material balances across various processes, from oil and gas separation to reactive distillation.
Information collaboration infrastructure system for realizing digital twins
AVEVA Asset Information Management is a solution that centralizes all information sources based on equipment tags, enabling visualization and information management. It eliminates silos across the entire plant lifecycle, providing accurate and up-to-date information to support efficient operations and decision-making. Furthermore, integration with the PI System allows for the unification of engineering data and operational data. With a user-friendly interface and advanced search capabilities, it enables engineers and operators to quickly access the information they need, thereby enhancing productivity. By implementing AVEVA Asset Information Management, companies can achieve both improved efficiency and reliability in asset management, strengthening their competitive edge.
Robust IIoT storage for Edge to Cloud connectivity
Edge Data Store (EDS) is software for Industrial IoT (IIoT) that enables the collection, storage, and access of operational data from sensors and devices that are not connected to control networks. Data that has been left behind due to unstable network connections or power in harsh environments can be accessed by placing it on the Edge Data Store, which is a cost-effective and robust device, allowing it to be utilized for actionable insights. By combining remote edge data with control networks, it becomes possible to gain a better overall understanding of industrial operations.
![[Information] Comprehensive DX promoted by Shell](https://image.www.ipros.com/public/product/image/40c/2001490463/IPROS71994271397394165990.png?w=280&h=280)
Infiltrating major energy companies and accelerating digital transformation!
This document presents a case where the energy company "Shell" transitioned from reactive to predictive operations, supporting engineers with data-driven insights and early determination that data is essential for achieving goals. The company, which extracts business value from real-time technology, applies existing enterprise contracts across many operational areas. These contracts are permeating a data-driven culture within the organization and accelerating digital transformation. [Contents (partial)] ■ Introduction ■ Company-wide intelligence through smart solutions ■ Advanced operations utilizing analytics ■ Saving millions of dollars through the digitalization of blowout preventers ■ Supporting greenhouse gas recovery with advanced analytics *For more details, please download the PDF or feel free to contact us.
Automatically adapts to changes in input volume, environment, and operating conditions! Can provide warnings before equipment failures occur.
We would like to introduce "AVEVA Predictive Analytics," which we handle. With native integration with the "AVEVA PI System," it is possible to deploy predictive/prescriptive maintenance activities among stakeholders without the need for data scientists or software development. Moreover, the success of predictive analytics solutions depends not only on algorithmic methods but also on expansion methods across the entire business. This no-code dedicated solution enables the deployment and maintenance of predictive monitoring programs throughout the organization. 【Features (partial)】 ■ Native integration with AVEVA PI System ■ Intuitive model building ■ Alerts and notifications ■ Fault diagnosis ■ Time-to-failure prediction *For more details, please download the PDF or feel free to contact us.
We will provide a second option with our core competence in software technology.
Our area of expertise lies in the development of control system software utilizing embedded software and networks. The system we are introducing this time is an application example of an open system (such as OpenCV) that leverages specialized knowledge in image processing and accumulated technology, contributing to reduced development time and enhanced product competitiveness. We utilize control system software technology to develop sensor network systems based on ARM embedded Linux and Android, automatic defect detection devices for LCD substrates, and efforts to improve the functionality of large-scale network systems, all tailored to meet our customers' cost requirements as a team of software engineers. - Power measurement systems - Power control systems - Measurement control systems - Measuring instrument systems - Image processing systems - Substrate inspection systems - Inline systems - Normalized correlation matching - Radiation systems - Radiation measurement and analysis systems - Congestion detection algorithms - Human detection algorithms - Filtering technology - Spatial simulation - Open Dynamics Engine - Template matching - Curved surface simulation - Gamma-ray spectrum concentration calculation *For more details, please feel free to contact us.
Finite Element Method 2D Axisymmetric and 3D Static Magnetic Field Analysis Software MAG
Magnetic field (magnetic field) analysis software (simulator) using finite element method for static analysis ■□■Features■□■ ■ Since it is integrated with the PHOTO series dedicated pre- and post-processing, data creation, analysis, and result processing can be performed as a series of operations. ■ It is integrated with other PHOTO series modules, allowing for easy coupled analysis, such as obtaining temperature distribution from heat generation calculated by electromagnetic field analysis. ■ A revolutionary speedup has been achieved by combining edge element method and ICCG method. (Dozens of times faster than conventional finite element methods) ■ The use of finite element method ensures stable solutions, making it safe for beginners to use. ■ Coupled calculations with stress analysis and fluid analysis are easy.
Transient response electric field analysis software using the finite element method.
Perform static analysis and transient response analysis Electric field analysis software using the finite element method (electric field simulator) ■□■Features■□■ ■Since it is integrated with the dedicated pre/post of the PHOTO series, data creation, analysis, and result processing can be performed as a series of operations. ■It is integrated with other PHOTO series modules, so for example, coupled analysis can be easily performed to obtain temperature distribution from heat generation determined by electromagnetic field analysis. ■Using the ICCG method, calculations are fast, allowing for analysis on a personal computer. ■Since it uses the finite element method, the solutions are stable, making it safe for beginners to use.
Realistic electromagnetic field analysis can be achieved at a low cost! It is also possible to customize by selecting the necessary features.
The "PHOTO series" offers analysis solvers that utilize the most suitable simulation methods for each broad area, ranging from high-frequency electromagnetic waves to low-frequency electric and magnetic fields, according to the analysis theme. Unlike other commercial software packages that handle all phenomena with a single analysis solver, we use the most appropriate analysis solver for the purpose, resulting in high analysis accuracy and detailed responsiveness to needs. Additionally, since you can select only the necessary modules suitable for the problem, the implementation costs can be kept economical. Functionality can also be easily expanded by adding modules, and by combining them, it is possible to handle coupled analyses such as heat generation due to eddy currents and stress or deformation due to electromagnetic forces. All products support three-dimensional problems, and the transient response analysis module can handle nonlinear materials.
![[Analysis Case] Electromagnetic Waves in Parallel Plates Using a Slide Interface](https://image.www.ipros.com/public/product/image/6d1/2000060369/IPROS07981005601145458329.gif?w=280&h=280)
Analysis is possible by one mesh interpolating the other mesh.
The analysis of electromagnetic waves in parallel plates using a slide interface was conducted for plane waves propagating in an air region sandwiched between metal plates (infinite parallel plates, perfect conductors) arranged above and below. This analysis was performed using a non-connected mesh (hereafter referred to as a non-connected mesh) with the slide interface applied. For more details, please download the catalog.
![[Analysis Case] Effect of Magnetic Sheet of RFID Card Using External Field Function](https://image.www.ipros.com/public/product/image/062/2000060385/IPROS92180494480385262066.gif?w=280&h=280)
What changes occur in the electromotive force when a magnetic sheet is attached?
If metal is installed near an RFID card, the electromotive force generated in the card's circuit by the external primary coil is significantly reduced due to the demagnetizing effect from the metal. To suppress this demagnetizing effect, we analyzed the changes in electromotive force when a magnetic sheet is attached to the card's surface using Photo-Eddyjω. For more details, please download the catalog.
![[Case Study] Eddy Current Testing Using an External Field Method (Non-Destructive Testing)](https://image.www.ipros.com/public/product/image/e5b/2000060390/IPROS45633917834039998805.gif?w=280&h=280)
We conducted "eddy current testing" analysis to detect surface defects on the conductor plate.
The eddy current testing (non-destructive testing) using the external field method has a significant analytical symmetry divided into the conductor plate and the probe. The probe consists of two types of coils: an excitation coil and a differential detection coil. We calculated the eddy current distribution when a current with a frequency of 500 Hz was applied to the excitation coil of the probe, as well as the induced electromotive force in the differential detection coil. For more details, please download the catalog.
This shows an example of magnetic field analysis when current is applied to a thin film head.
The number of nodes in the analysis of the thin film head is 65,670, and the number of elements is 61,089. The analysis conditions include the electrical conductivity of the magnetic material at 5×10^6 [Sm-1], and the magnetic properties of the magnetic material were based on the relationship between magnetic flux density and magnetic field (B-H curve) shown in the figure. For more details, please download the catalog.
![[Analysis Case] Analysis Case of Hinge-Type Electromagnetic Relay](https://image.www.ipros.com/public/product/image/7c8/2000060401/IPROS09775813543743015527.gif?w=280&h=280)
The subject of analysis is a hinge-type electromagnetic relay switch.
The analysis case of hinge-type electromagnetic relays requires mesh division of space in the finite element method. Therefore, handling the motion of objects in the finite element method has been considered a very difficult category of analysis, as it necessitates the manipulation of meshes, including spatial meshes. In the PHOTO-Series, we have newly developed a unique analysis function that automatically deforms the spatial mesh into an optimal shape according to the motion of the object, thus solving this problem. For more details, please download the catalog.
![[Analysis Case] Cogging Torque Analysis of Claw Pole Motors](https://image.www.ipros.com/public/product/image/ac0/2000060405/IPROS61873611324992112476.gif?w=280&h=280)
The subject of analysis is a claw pole motor.
The claw pole motor is divided into the rotor part and the stator part, each having a structure as shown in the figure. By incorporating the magnetization of the permanent magnet obtained through pre-magnetization analysis, the rotor is rotated in an unloaded state to perform torque analysis. Although this is an analysis involving rotation, it can be conducted without regenerating the air mesh of the gap (the space between the rotor and stator) using PHOTON's uniquely developed new slide interface. For more details, please download the catalog.
![[Analysis Case] Analysis of Induction Heating](https://image.www.ipros.com/public/product/image/fd3/2000060428/IPROS02206053096984310996.jpeg?w=280&h=280)
We conducted a coupled analysis of induction heating.
The analysis of induction heating shows an example of the eddy current and temperature field analysis (induction heating analysis) of a metal tube with a notch, when a coil carrying an alternating current of 500 kW at a frequency of 800 kHz is energized around the metal tube. The analysis model is created to include the object of analysis and the surrounding air portion. For more details, please download the catalog.
Case study collection available! Software that can analyze temperature distribution due to induction heating.
"PHOTO-EDDY+THERMO" or "PHOTO-EDDYjω+THERMO" is a dedicated module for coupled analysis that combines magnetic field analysis and thermal conduction analysis. The transfer of heat generation density is automatically performed without the need for files, allowing even beginners to confidently conduct strong coupled analysis (bidirectional). [Examples of Applications] ◆ Quenching of gears by induction heating ◆ Induction heating analysis of steel plates (coupled analysis of magnetic field and heat) ◆ Analysis of induction heating… and more [For more details, please download the catalog or feel free to contact us] ↓ ↓ ↓ ↓ ↓ ↓
[Customizable] Simulation software that can visualize magnetic field distribution and eddy current density distribution! Also analyzes eddy current deep penetration method. *[Web consultations are currently well received]*
The electromagnetic field analysis software "PHOTO-Series" is a simulation tool that can visualize magnetic field distribution and eddy current density distribution. It also analyzes the eddy current deep flaw detection method, which is one of the non-destructive testing methods for detecting defects. 【Features】 ● Each product is low-cost, allowing for the construction of systems composed of numerous modules, including coupled problems with electromagnetic field analysis, heat conduction, stress, and fluid analysis, at a low price. ● Each product is integrated with dedicated pre- and post-processing tools, equipped only with the necessary functions for electromagnetic field analysis, making it easy for beginners to operate smoothly. ● An academic price is available for use in educational institutions (half the regular price). ◆ If you are interested, please contact us via the 'Contact Form'.
Magnetic field (magnetic field) analysis software (simulator) using the magnetic moment method for static analysis *No air mesh required.
Magnetic field (magnetic field) analysis software (simulator) using the magnetic moment method for static analysis ■□■Features■□■ ■ You can create an analysis model without creating an air region. ■ It is integrated with the PHOTO series dedicated pre-post, allowing for a seamless operation from data creation to analysis and result processing. ■ By setting the analysis type to an inverse problem, it is possible to infer the magnetization of a magnetic material from the magnetic flux density distribution file. ■ You can create display elements to evaluate the analysis values in space.
3D magnetic field analysis software (magnetic field simulator) using a combination of finite element method and H-method *No air mesh required.
■ Magnetic field/magnetic field analysis software (magnetic field simulator) using a combination of finite element method and H-method, capable of performing static analysis and transient response analysis. ■ Can handle three-dimensional problems. ■□■ Features ■□■ ■ Can create analysis models without creating air regions. ■ Integrated with the PHOTO series dedicated pre- and post-processing, allowing data creation, analysis, and result processing to be performed as a single operation. ■ Achieves groundbreaking speed improvements through the combination of edge element method and ICCG method (dozens of times faster than conventional finite element methods). ■ Provides stable solutions using finite element method, making it safe for beginners to use.
Software for coupled analysis of magnetic fields and heat conduction using the finite element method, performing static analysis and transient response analysis.
This is a software for coupled analysis of magnetic fields/magnetic fields and heat conduction using the finite element method, capable of performing static analysis and transient response analysis. It can handle three-dimensional, two-dimensional, and axisymmetric problems. ■□■Features■□■ ■Since it is integrated with the PHOTO series dedicated pre- and post-processing, data creation, analysis, and result processing can be performed as a series of operations. ■A groundbreaking speedup has been achieved through the combined use of edge element method and ICCG method (dozens of times faster than conventional finite element methods). ■The use of finite element method ensures stable solutions, making it safe for beginners to use. ■Since EDDY (magnetic field analysis module) and THERMO (heat conduction module) are integrated, the transfer of heat generation density is automatically executed without the need for files. ■It is also possible to use EDDY and THERMO independently.
This is a software for coupled analysis of magnetic fields/magnetic fields and heat conduction using the finite element method, performing static analysis and frequency response analysis.
This is a software for coupled analysis of magnetic fields/magnetic fields and heat conduction using the finite element method, capable of performing static analysis and frequency response analysis. It can handle three-dimensional, two-dimensional, and axisymmetric problems. ■□■Features■□■ ■Since it is integrated with the PHOTO series dedicated pre- and post-processing, data creation, analysis, and result processing can be performed as a series of operations. ■A revolutionary speed-up has been achieved through the combined use of edge element method and ICCG method (tens of times faster than conventional finite element methods). ■The use of finite element method ensures stable solutions, making it user-friendly even for beginners. ■Since EDDYjω (magnetic field analysis module) and THERMO (heat conduction analysis module) are integrated, the transfer of heat generation density is executed automatically without the need for files. ■It is also possible to use EDDYjω and THERMO independently.
![[Analysis Case] Electromagnetic Field Analysis of E-Plane T-Junction Waveguide](https://image.www.ipros.com/public/product/image/d5d/2000763633/IPROS68861440671259662792.png?w=280&h=280)
Using the analysis module "PHOTO-WAVEjω"! The scattering matrix was obtained from the analysis results.
We conducted an analysis using the finite element method to determine the distribution of electromagnetic waves input from each port in a T-shaped waveguide used for signal processing in radar and other applications. Three ports were set up in the E-plane T-junction waveguide. Due to symmetry, a 1/2 model was created, with natural boundary conditions on the XY plane and symmetric boundary conditions on the other sides. As a result, the absolute values of S31 and S13 calculated were 0.644 and 0.631, respectively, with an error of 2.0%. [Case Summary] ■ Analysis Module: PHOTO-WAVEjω ■ Analysis Results - The absolute values of S31 and S13 calculated were 0.644 and 0.631, respectively, with an error of 2.0%. *For more details, please refer to the related links or feel free to contact us.
Estimate electromagnetic waves from a distance using two different methods and compare the results! The shape was modeled in full.
The Yagi-Uda antenna is a directional antenna composed of a waveguide made up of multiple short elements, a long element reflector, and a feed mechanism positioned between them. The electromagnetic waves radiated from the feed mechanism are analyzed using the finite element method, and based on the results, far-field plane waves are estimated. The feed mechanism radiates electromagnetic waves polarized in the Z-axis direction, and the behavior of the electromagnetic waves in the air region surrounding the entire antenna is analyzed using the finite element method. Next, based on those results, the electromagnetic waves in the far field are estimated using two different methods, and the results are compared. The shape is modeled as a full model. [Software Used] ■ PHOTO-WAVEjω *For more details, please refer to the related links or feel free to contact us.
![[Analysis Case] Scattering Analysis of Plane Waves by a Dielectric Sphere](https://image.www.ipros.com/public/product/image/528/2000763713/IPROS91566975360380790045.png?w=280&h=280)
Using the software "PHOTO-WAVEjω"! Analyzing the scattered waves after hitting a sphere using the finite element method.
This is an example of estimating the scattered wave in the far field when a plane wave is incident on a scattering body, using the finite element method. A plane wave polarized in the X-axis direction is incident in the Z-axis direction, and the scattered wave after it hits this sphere is analyzed using the finite element method. Next, based on those results, the scattered wave in the far field is estimated using two different methods, and the results are compared. The shape is modeled in full. 【Software Used】 ■PHOTO-WAVEjω *For more details, please refer to the related links or feel free to contact us.
![[Case Study] Electromagnetic Wave Analysis of Right-Angle Corner in H-Plane Waveguide](https://image.www.ipros.com/public/product/image/f09/2000763733/IPROS25769334317410418778.png?w=280&h=280)
Analysis was also conducted in the absence of a metal post! The analysis results at a frequency of 10.13 [GHz] are shown.
We will introduce a case study analyzing the frequency dependence of the reflection rate by placing metal posts that suppress the reflection of electromagnetic waves at 10 GHz. Impedance boundary conditions were set at the exit. The walls of the waveguide and the metal posts were treated as perfect conductors, and the input was provided as the TE10 electric field [V/m]. Additionally, an analysis was conducted for the case without metal posts for comparison. 【Case Overview】 ■ Software Used: PHOTO-WAVEjω ■ Analysis Conditions - Waveguide: WRJ-10 (22.9mm × 10.2mm) - The walls of the waveguide and the metal posts are perfect conductors - The input was provided as the TE10 electric field [V/m] - Impedance boundary conditions were set at the exit *For more details, please refer to the related links or feel free to contact us.
![[Analysis Example] Electromagnetic Wave Analysis Animation Library for Waveguides](https://image.www.ipros.com/public/product/image/888/2000763827/IPROS09437893911385746829.png?w=280&h=280)
Introducing analysis examples such as "circular cavity" and "rectangular iris-coupled waveguide filter"!
On this page, we introduce electromagnetic wave analysis animations of waveguides such as "Magic T," "E-plane T-junction waveguide," and "twisted waveguide." 【Overview】 ■ Magic T ■ E-plane T-junction waveguide ■ Twisted waveguide ■ Circular cavity ■ Rectangular iris-coupled waveguide filter *For detailed information about the examples, please refer to the related links. For more information, feel free to contact us.
![[Case Study] Analysis of Current Density Distribution in Superconducting Tape](https://image.www.ipros.com/public/product/image/e80/2000763896/IPROS94894548883369229440.png?w=280&h=280)
No need for air mesh! Load and analyze the interpreter program with pre-set conditions at runtime.
This is an example of transient magnetic field analysis using the H method, where the current distribution of a superconducting tape was analyzed. The "n-value model" was used for the E-J characteristics of the superconducting tape. By using the magnetic field analysis module "PHOTO-EDDYTM," it is possible to analyze with a mesh of only the conductor, eliminating the need for an air mesh. 【Case Overview】 ■ Software Used: PHOTO-EDDYTM ■ Analysis Conditions - Current Value: 50[A] (maximum)… time-varying according to a function - Material Conditions: Relative permeability 1.0, electrical conductivity according to the program [S/m] - The "n-value model" was used for the E-J characteristics of the superconducting tape. *For more details, please refer to the related links or feel free to contact us.
![[Analysis Case] Eddy Current Analysis of Perforated Conductors Using External Coils](https://image.www.ipros.com/public/product/image/892/2000763907/IPROS55386049140531304697.png?w=280&h=280)
Comparison under three conditions: FEM, external field coils, and measurement values! An analysis with the coils moved was also conducted.
We will introduce the analysis results using the finite element method (FEM) with coils and external field coils for the same analysis target. We adopted "Team Workshop Problem 7," which involves placing a coil on a perforated conductor. Since this problem has measurement values, we compared the results under three conditions: FEM, external field coil, and measurement values, and also conducted an analysis with the coil moved. The results from the external field and FEM overlapped in the graphs, and the comparison with the measurement values was also favorable. 【Case Overview】 ■ Software Used: PHOTO-EDDYjω ■ Analysis Conditions - Frequency: 200 [Hz] - Current Value: 2742 [AT] - Electrical Conductivity of Conductor: 3.526×10^7 [S/m] ■ Results from External Field and FEM: The graphs overlapped, and the comparison with measurement values was also favorable. *For more details, please refer to the related links or feel free to contact us.
![[Analysis Case] Magnetic Field Analysis of Current Sensor (CT)](https://image.www.ipros.com/public/product/image/b18/2000763914/IPROS75171623609546777071.png?w=280&h=280)
The core uses a high permeability magnetic material! The analysis model was created using symmetry, resulting in a 1/2 model.
We will introduce a case where we analyzed the current flowing through the cable and the induced voltage and current values flowing through the secondary coil. The analysis model utilizes symmetry, using a 1/2 model, and a high permeability magnetic material is used for the core. The current sensor consists of a ring-shaped core and winding, with the measured current flowing through the cable at the center of the core, allowing us to obtain a small current flowing through the winding (secondary side). 【Case Overview】 ■ Software Used: PHOTO-EDDYjω ■ Analysis Conditions - Current value of the primary coil: 10[A] - Frequency: 50[Hz] - Number of turns in the secondary coil: 1000[turns] - Load resistance of the secondary coil: 100[Ω] *For more details, please refer to the related links or feel free to contact us.
