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Ansys has launched a learning programme for those who want to improve their engineering skills with Ansys software. According to the official announcement. AEye and ANSYS are accelerating autonomous driving safety by enabling virtual prototyping of iDAR™ to speed design, testing and validation of autonomous. How do I remove ANSYS lock files? To protect against data loss, the ANSYS program employs a file-locking mechanism. File locking helps to prevent you or.

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How do I remove ANSYS lock files?

To protect against data loss, the ANSYS program employs a file-locking mechanism. File locking helps to prevent you or another user from inadvertently opening a new job with the same name and in the same working directory as a currently running job.

When you open a job (jobname) from a given working directory, ANSYS creates a corresponding lock file called jobname.lock in that directory.  The lock file exists for as long as your job is running.  If you or someone else attempts to open another job of the same name (and in the same directory) as your currently running job, ANSYS detects the existence of the lock file and does not open the new job.  In interactive mode, ANSYS displays a dialog indicating that the file is locked, offering the option to override the lock.  In batch mode, the program exits, leaving the lock file intact.

To find and remove Ansys lock files, run
find ~/ -name “*.lock” -exec rm {} \;

ANSYS creates and checks for lock files by default.  If you prefer to disable the file-lock feature, specify the ANSYS_LOCK=OFF environment variable in your config60.ans file.

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Template-based design automates future routine work, and automated documentation facilitates report generation A lot of steel structures such as cranes, heavy machinery and other equipment subjected to repetitive loading is highly likely to develop cracks or failures because of the fatigue damage. The cost of every hour of equipment downtime […]

Beam Member Check in Ansys with SDC Verifier according to Eurocode 3. Structural Fire Design

We made a video tutorial to show how easy you can perform Beam Member Check in Ansys according to Eurocode 3. Structural Fire Design with the help of SDC Verifier. 00:00 Introduction 00:27 Opening model (Lattice structure) 01:15 Adding EC 3 Fire Design Standard to SDC Verifier project 01:58 Input […]

2:08 SDC Verifier Introduction 11:45 What’s new in SDC Verifier 5.3 12:08 Integration into ANSYS Mechanical Tree (Ansys R2, R3) 15:35 Modules in SDC Verifier 16:27 Stiffener Buckling Check DNV 2010 and Panel Finder Tool 23:02 Effective width Tool 31:00 Eurocode3 part 1-2 (beta) (Fire Design) 32:00 Plot Labels 34:15 […]

00:07 SDC Verifier Introduction 14:51 Plate Buckling Checks 17:00 Creation of Load Sets and Load Group (Envelope) 18:49 Plates recognition using Panel Finder tool. 26:16 Plate Buckling tables and plots. 31:20 Reporting: Preparing and generating the final report on a check.

00:05 SDC Verifier Introduction 14:44 How to start SDC Verifier project in Ansys Workbench 21:24 Beam checks according to AISC Standard Demo

00:05 SDC Verifier Introduction 22:20 Questions 29:10 Automatic Weld Recognition Demo 1:02:27 Questions

Timecodes for browsing through webinar 2:37 – Introduction. What is SDC Verifier 8:56 – Recognition of structural items (Recognition tools) 13:04 – Implemented codes 14:27 – SDC Reporting (Short description) 17:17 – SDC Verifier benefits 24:16 – Why sell SDC Verifier 28:25 – How to sell SDC Verifier 31:20 – […]

Live demonstration of SDC Verifier working with ANSYS Beam Buckling according to AISC360-10. Time codes: 1:02 Getting started in Workbench 1:48 Create new project 2:48 Job Explanation 6:32 Tables 10:48 Recognition of buckling lengths 17:44 AISC360-10 24:10 Governing Loads 27:50 Reporting

SDC Verifier: Get Started Tutorial

An introduction tutorial to get familiar with the software. It demonstrates how to create a project, define loads and load combinations, and quickly generate calculation results report. This step-by-step tutorial is designed to get you started with main SDC Verifier features: Launch SDC Verifier; Creating new project; Create Combinations and Envelope; […]

Short video on how to start a simple project in SDC Verifier 5.2 and ANSYS Workbench 19.2. You can also try our Get Started SDC Verifier for Ansys tutorial.

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How to Export Cas & Dat Files From Fluent

Quote:

Originally Posted by LuckyTranView Post

Probably because you asked a question about Workbench in the Fluent forum where more users use Fluent exclusively outside of the workbench environment.

There's no reason to think my inquiry was invalid because of using Fluent within WB. Nowhere in the forum, is there a disclaimer stating such and it's preposterous to think of such. It's an ANSYS tool that has been integrated into WB, giving every reason to believe it could be used within WB. In my experience thus far, Fluent functions fine within WB. I started my Fluent journey blindly, not knowing anything but to open WB and insert a Fluent system. And so far, I've had good luck. However, I have run into countless people who scorn Fluent's alleged dysfunctionalities when operated within WB. Perhaps me coming in blindly was to my benefit, because I have an open mind about how it can be used in various ways, outside of the mainstream.

Quote:

Originally Posted by LuckyTranView Post

Btw the usual format is .cas and .dat (not gnuzipepd). If you know these things already. If you're at the level that you are writing gnuzipped files, it's really odd that you don't know how to write a .cas & .dat file.

This is not so within WB. WB zips them to *.gz format by default. So it's not as if I willingly zipped them, demonstrating advanced user understanding of the tool. And in my opinion, it's probably more sensible to zip them because it helps manage disk spacing.

Quote:

Originally Posted by LuckyTranView Post

Looking back, I think it's better than you spent the time in Workbench/Fluent to learn it on your own.

I agree completely. Experience on one's own is a great teacher. But a little outside help always greases the wheels a little better.

Quote:

Originally Posted by LuckyTranView Post

Also this is not a support/service Forum on Ansys or any software. You should be expressing your discontent on the Ansys customer support website if these are your feelings. Here your mileage will vary as we do not have service guarantees here, only (sometimes) goodwill.

I was not seeking service. I was asking a usage question and again, I saw no disclaimers on the forum stating the specificity of approved inquires that are allowed. And my discontent was toward the lack of response I received from the user base here on the forum, not at the ANSYS tool. Yes, I noted a clunky export GUI, but that was not my focus of the statements and I stated that it was easily worked around. Goodwill (sometimes)? Why not all the time? I think users here should have more goodwill. This will lead to better vibes in the community, driving usage, innovation, research, and enjoyment higher around the tool, Fluent. It's a complicated tool and much of the knowledge can be shared by the more experienced users onto the newer users, thus propagating the life of the tool into the future. Because if all of the experienced users are unwilling to share goodwill and reach out for the benefit of new folks, eventually the tool itself, that we all want to use and enjoy, will die.
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Support

Our subscribers are able to use our virtual Cloud accounts hosted here in Kingston, Ontario, if they do not have access to certain CAD tools at their home universities. Figure 1 shows the CMC Microsystems’ Cloud account hardware configuration.

These accounts have recently been assigned additional master disk space for temporary “scratch” file read/write activity. The reason for this addition: During simulations, ANSYS software will create many files as the program solves a set of numerical values at mesh points, and uses this solution set to calculate its next solution set, continuing until the value difference between successive solutions sets is acceptably low.

These generated files can overwhelm local account memory and mydata persistent file storage, so our IT group has assigned more space to each account under a /scratch directory. This is how to set your ANSYS software to use this extra disk.

Figure 1. CMC Cloud account hardware configuration.

Setting a “/scratch” directory in ANSYS Electronics Desktop (EDT)

To point your ANSYS EDT software to your /scratch directory, open the Options windows using the menu link Tools -> Options -> General Options… -> Directories, as shown in Figure 2. Select the Override checkbox and enter the name of the scratch directory you have created, using your virtual account identity; for example, if your assigned account name is “v34567”, you would create and use the directory and path “/scratch/v34567”. Close and re-open ANSYS EDT, checking to make sure you are setting your Temp: path correctly.

Figure 2. Setting a Temporary Files (Scratch) directory for ANSYS EDT simulations.

Setting a “/scratch” Directory in ANSYS Workbench (Fluent, Mechanical, Mechanical APDL)

To point your ANSYS Workbenchch software to your /scratch directory, open the Options windows using the menu link Tools -> Options -> Project Management, as shown in Figure 3. Enter the name of the scratch directory you have created, using your virtual account identity; for example, if your assigned account name is “v34567”, you would create and use the directory and path “/scratch/v34567”. Close and re-open ANSYS Workbench, checking to make sure you are setting your Default Folder for Temporary Files path correctly. Then open your project and proceed with your simulation work.

Figure 3. Setting a Default Folder for Temporary Files in ANSYS Workbench.

Setting a “/scratch” Directory in the Fluent Stand-alone Program

Those subscribers that launch the Fluent CAD tool directly may designate the /scratch directory using the menu path File -> Preferences -> Meshing Workflow and type in the /scratch directory path.

Figure 4. Setting the Temporary files folder from within Fluent from File -> Preferences.

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Connect the Digital Thread with Hybrid Digital Twins, AI-Enabled Simulation, and Cloud Computing

Digital convergence is enabling industries to make the most of the data they collect to inform decisions at every stage of the product life cycle, connect information technology (IT) with operational technology (OT), and capitalize on new business models. Where does simulation engineering fit in the broader digital convergence discussion?

Pillars of Innovation: Ansys CTO Talks Digital Twins, Vertical Health Care, and More at IEEE

Leading its second day of panels at IEEE, Prith Banerjee, Chief Technology Officer at Ansys, delivered a keynote presentation that featured Ansys’ long-term strategies to enable simulation-based product innovation across industries.

Supporting Phased Array Radar Development in Autonomous Vehicles with Ansys HFSS

Ansys Gets Into Open Source With GitHub

Simulation Software in Product Development Drives Digital Transformation at Lightspeed

PTC’s Brian Thompson and Ansys’ Mark Hindsbo delve into the finding of a three-year Ansys-sponsored study quantifying the return on Investment in Simulation-Led Design Exploration and explore the role of simulation software in the product development process to drive and quicken digital transformation. View this white paper to learn more.

Democratize Simulation with Automation

With enhanced integration between Ansys optiSLang and Minerva, democratization of simulation automation is just a few clicks away, enabling experts and nonexperts to reap the benefits of simulation.

How to Meet the Top 5 Simulation Process and Data Management Challenges

A typical day in the life of a simulation engineer involves data gathering data, referencing historical data, pre-processing the models, solving the simulation problem either locally or via high-performance computing (HPC), post-processing the results, generating reports and archiving data. The process and the level of interaction quickly get complex as more tools, physics and multiple teams are involved.

Fluid Dynamic Simulations Advance Appliance Designs

Tighter environmental regulations coupled with more sophisticated user experience requirements pushes the designs into territories where subtle physical behavior starts to play a more prominent role.

Electric Machines: Simulating the Power to Win

To beat the competition in the electric vehicle market automakers are focused on ensuring EV powertrains are efficient to design, manufacture and operate. As they race forward with EV development, engineers are increasingly using simulation to leverage the potential of holistically optimizing the powertrain with a systems engineering approach.

Women in Technology: Simulating Sensors to Advance Autonomous Automobiles

While autonomy represents an incredibly complex engineering challenge spanning multiple functions, perception systems play a foundational role. Automotive autonomy is only possible if the sensors mounted on the car accurately gather information about the surrounding environment and transmit that data to other systems — such as steering and braking — to trigger an appropriate, safe response.

Simulate How Permanent Magnets Impact Medical Implants

Using Ansys Maxwell, users can define arbitrary magnet assemblies and evaluate magnetic fields in 3D space.

How one Air Race E team Overcame a Critical Design Challenge With Simulation

Why Medical Device Design Requires Material Information Management

Like other product design engineers, medical device engineers need to know the traditional mechanical properties of a material they plan to use to ensure it’s up to the task. But that’s not enough. They also need to know how the body will react to the device and how the device will react to the body.

Take Your Engineering Simulation Workflow to the Next Level

Working with the right data is critical to an efficient workflow, but with all the different stakeholders involved in product design and development, how do you know where the right data is?

The Fundamentals of FEA Meshing for Structural Analysis

To conduct a CAE simulation, there are three important steps to an analysis: pre-processing, solving and post-processing. This post discusses the FEA pre-processing step, specifically the importance of a good quality mesh.

How Partnerships Power Simulation

The old, siloed approach to product design and development is being replaced by streamlined workflows where an array of hardware and software needs to work together to foster innovation.

Simulation User Survey Results: Evolving Workflows Affect HPC Usage

Ansys launched a research survey last year to find out how engineering organizations are using HPC resources for engineering simulation.

Ansys and GLOBALFOUNDRIES Team to Accelerate Photonic Integrated Circuit Design

How to Model and Simulate Complex Electric Motors

3D electromagnetic problems become more complex in multiphysics simulations such as noise-vibration and harshness (NVH).

Earth Day 2021: Simulation Advances Sustainability

Engineers understand that the individual components they design and simulate are part of larger assemblies, which are part of larger systems, which are part of an ecosystem.

Predator Cycling Optimizes the Cycling Experience With Simulation

Winning the War on COVID with Ansys Fluent

Renowned researcher Bert Blocken, Ph.D., was recently recognized by Engineering.com alongside other pioneering minds, such as Elon Musk and Ansys CEO Ajei Gopal, for his groundbreaking academic research activities in computational fluid dynamics, wall function development and analysis of basic flow phenomena.

Register for Simulation World 2021 to Engineer What’s Ahead

Aerodynamics Simulations with Ansys CFX and Fluent in the UberCloud: Part 1

Aerodynamics Simulations with Ansys CFX and Fluent in the UberCloud: Part 2

Engineering Simulations using Ansys in the Cloud: Part 2

On page 40 is the second part of an article presenting a selection of case studies dealing with engineering simulation in the cloud using ANSYS software LS-DYNA, HFSS, and ANSYS Discovery Live; the first part appeared in the previous edition of the EnginSoft magazine and presented case studies based on ANSYS CFX and Fluent.

Engineering Simulation using Ansys in the Cloud: Part 1

In this article (page 35), the first in a series, UberCloud presents a series of case studies of cloud-based services for engineering-specific applications and use cases that objectively demonstrate the progress of cloud computing in this sector over the past seven years.

Ansys Discovery Virtual Launch

When the Pressure Is On: Preventing Well Blowouts

Green Machine

ANSYS Simulation: Room Contamination During Respiratory Therapy

Liberty University Professor of Mechanical Engineering Dr. Wayne Strasser was recently asked by a company focused on the development of respiratory therapy products to aid them in their research on the spread of COVID-19. The team used Ansys simulation solutions to study the exhale of atomized droplets of saliva and mucus during respiratory therapy in a hospital room.

ANSYS Simulation: Inhalation and Drug Delivery

By modeling how inhalers deliver medication to the lungs, simulation helps medical device companies improve inhaler design and helps physicians train their patients on how to use the inhalers for greatest effect. Modeling done by Dr. Yu Feng's Computational Biofluidics and Biomechanics Laboratory at Oklahoma State University.

ANSYS Simulation: Ventilator Design and Manufacturing

The medical device industry uses simulation to optimize the design of ventilators. Physics-based simulation is the most effective method to accelerate product development and ensure these devices reach those in need as quickly as possible. Modeling work performed by ARELabs.

ANSYS Simulation: Vaccine Production

Once a vaccine has been identified, one of the biggest challenges facing the biopharma industry is scaling up the production of the vaccine from laboratory to industrial scale. By using simulation in a virtual environment, drug companies can increase their chances of getting the scale-up process right the first time.

ANSYS Simulation: Disinfection

Decontaminating rooms and facilities – whether in preparation for patients or in places where the virus has been identified – helps contain the spread of the virus and protect the health of the vulnerable. Simulations performed by Ansys partner InSilicoTrials Technologies optimizes the decontamination process to ensure clean rooms.

ANSYS Simulation: Negative Pressure Room

Negative pressure rooms (NPRs) can help to reduce healthcare staff's exposure to the virus while attending patients. Simulation demonstrates different room designs of NPRs and enables teams to optimize the room design, inlet vent placement and blower capacity to avoid oral and nasal plumes from recirculating in the room.

ANSYS Simulation: Fit the Mask Properly

Wearing a face mask correctly for an extended period can be uncomfortable and cause irritation, however, it is necessary to ensure the effectiveness of the mask.

ANSYS Simulation: Wear a Mask

Masks can reduce the risk of contaminating others by up to 6 times. Adjustments can be made to ensure masks are sealed properly to reduce the risk of possible exposure.

ANSYS Simulation: Leave Additional Space When Exercising

Standard social distancing guidelines are insufficient when exercising outside. Analysis by Ansys partners Bert Blocken and Fabio Malizia at TUe & KU Leuven has revealed that substantially more space is required to avoid droplets from the runner or cyclist in front of you.

ANSYS Simulation: Maintaining Social Distancing

Viral droplets spread quickly throughout the air. The droplets from a cough will spread to the face, neck and clothing of someone one meter away. At two meters, the risk decreases significantly because gravity pulls the carrier droplets to the ground.

A Revolution in Healthcare with Simulation

A Revolution in Healthcare from ANSYS

Watch this video to get an overview of how ANSYS simulation is helping medical device and pharmaceutical companies save lives by using in silico tests to safely develop innovative devices and treatment methods in virtual human laboratories. Learn how simulation leads to an incredibly high return on investment for these companies, and how regulatory agencies like the FDA are starting to allow simulation data to be used as part of a faster approval process.

ANSYS Discovery Live Applications and Use Cases

ANSYS Discovery Live is a groundbreaking approach to design, allowing anyone to incorporate engineering simulation earlier into product development. Watch this video to see simulation results in real time demonstrating the design of stents, skis, wireless battery charging systems and control board covers for airplanes — a few of the unlimited applications of Discovery Live.

How nTop Platform was used to design, analyze and print a fuel-cooled oil cooler

nTop engineers designed, analyzed and printed a fuel-cooled oil cooler using nTop Platform, ANSYS CFX and a new additive aluminum alloy developed by HRL Laboratories. This blog takes you from start to finish in the series that began in late 2019.

Unlock Breakthrough Heat Exchanger Designs with Gyroids

Engineers can now use additive manufacturing, topology optimization and computational fluid dynamics (CFD) to build, shape, optimize and evaluate designs that were previously impossible to produce.

Why ANSYS Bet on Aras PLM Technology, and Why Aras Tends to Become a “Silent Partner”

“We believe that simulation is crucial to developing tomorrow's next generation products, and that better data and process management of simulations are needed to enable the digital processes of the future that will support these products,” Peter Schroer . "We see ANSYS and the Aras partnership as a potential game changer to connect simulation to technical processes for traceability, access and reuse throughout the product lifecycle. "

What is Simulation-Led Design

What is Pervasive Engineering Simulation

Microsoft partner ANSYS extends ability of Azure Digital Twins platform

“Collaborating with ANSYS to create an advanced IoT digital twins framework provides our customers with an unprecedented understanding of their deployed assets’ performance by leveraging physics and simulation-based analytics.” — Sam George, corporate vice president of Azure IoT, Microsoft

Rev-Sim Coffee Break Series: Part 19

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Table of Contents

1. About This Reference
1.1. Conventions Used in This Reference
1.1.1. Product Codes
1.1.2. Applicable Products
1.2. Terminology
1.3. Command Characteristics
1.3.1. Data Input
1.3.2. Free-Format Input
1.3.3. Nonrestrictive Data Input
1.3.4. Condensed Data Input
1.3.5. Units
1.3.6. Command and Argument Defaults
1.3.7. File Names
1.3.8. Star and Slash Commands
2. Command Groupings
2.1. SESSION Commands
2.2. DATABASE Commands
2.3. GRAPHICS Commands
2.4. APDL Commands
2.5. PREP7 Commands
2.6. SOLUTION Commands
2.7. POST1 Commands
2.8. POST26 Commands
2.9. AUX2 Commands
2.10. AUX3 Commands
2.11. AUX12 Commands
2.12. AUX15 Commands
2.13. Mapping Processor Commands
2.14. DISPLAY Program Commands
2.15. REDUCED Order Modeling Commands
3. Command Dictionary
I. Connection Commands
~CAT5IN - Transfers a .CATPart file into the ANSYS program.
~CATIAIN - Transfers a CATIA model into the ANSYS program.
~PARAIN - Transfers a Parasolid file into the ANSYS program.
~PROEIN - Transfers a Creo Parametric part into the ANSYS program.
~SATIN - Transfers a .SAT file into the ANSYS program.
~UGIN - Transfers an NX part into the ANSYS program.
II. A Commands
A - Defines an area by connecting keypoints.
AADD - Adds separate areas to create a single area.
AATT - Associates element attributes with the selected, unmeshed areas.
ABEXTRACT - Extracts the alpha-beta damping multipliers for Rayleigh damping.
*ABBR - Defines an abbreviation.
ABBRES - Reads abbreviations from a coded file.
ABBSAV - Writes the current abbreviation set to a coded file.
ABS - Forms the absolute value of a variable.
ACCAT - Concatenates multiple areas in preparation for mapped meshing.
ACCOPTION - Specifies GPU accelerator capability options.
ACEL - Specifies the linear acceleration of the global Cartesian reference frame for the analysis.
ACLEAR - Deletes nodes and area elements associated with selected areas.
ADAMS - Performs solutions and writes flexible body information to a modal neutral file (Jobname.MNF) for use in an ADAMS analysis.
ADD - Adds (sums) variables.
ADDAM - Specifies the acceleration spectrum computation constants for the analysis of shock resistance of shipboard structures.
ADELE - Deletes unmeshed areas.
ADGL - Lists keypoints of an area that lie on a parametric degeneracy.
ADRAG - Generates areas by dragging a line pattern along a path.
AEROCOEFF - Computes the aero-damping and stiffness coefficients and writes them to an APDL array.
AESIZE - Specifies the element size to be meshed onto areas.
AFILLT - Generates a fillet at the intersection of two areas.
AFLIST - Lists the current data in the database.
AFSURF - Generates surface elements overlaid on the surface of existing solid elements and assigns the extra node as the closest fluid element node.
*AFUN - Specifies units for angular functions in parameter expressions.
AGEN - Generates additional areas from a pattern of areas.
AGLUE - Generates new areas by "gluing" areas.
AINA - Finds the intersection of areas.
AINP - Finds the pairwise intersection of areas.
AINV - Finds the intersection of an area with a volume.
AL - Generates an area bounded by previously defined lines.
ALIST - Lists the defined areas.
ALLSEL - Selects all entities with a single command.
ALPHAD - Defines the mass matrix multiplier for damping.
AMAP - Generates a 2-D mapped mesh based on specified area corners.
AMESH - Generates nodes and area elements within areas.
/AN3D - Specifies 3-D annotation functions
ANCNTR - Produces an animated sequence of a contoured deformed shape.
ANCUT - Produces an animated sequence of Q-slices.
ANCYC - Applies a traveling wave animation to graphics data in a modal cyclic symmetry analysis.
ANDATA - Displays animated graphics data for nonlinear problems.
ANDSCL - Produces an animated sequence of a deformed shape.
ANDYNA - Produces an animated sequence of contour values through substeps.
/ANFILE - Saves or resumes an animation sequence to or from a file.
ANFLOW - Produces an animated sequence of particle flow in a flowing fluid or a charged particle traveling in an electric or magnetic field.
/ANGLE - Rotates the display about an axis.
ANHARM - Produces an animated sequence of time-harmonic results or complex mode shapes.
ANIM - Displays animated graphics data for linear problems.
ANISOS - Produces an animated sequence of an isosurface.
ANMODE - Produces an animated sequence of a mode shape.
ANMRES - Performs animation of results over multiple results files in an explicit dynamic structural analysis or fluid flow analysis with remeshing.
/ANNOT - Activates graphics for annotating displays (GUI).
ANORM - Reorients area normals.
ANPRES - Produces an animated sequence of the time-harmonic pressure variation of an engine-order excitation in a cyclic harmonic analysis.
ANSOL - Specifies averaged nodal data to be stored from the results file in the solution coordinate system.
ANSTOAQWA - Creates an AQWA-LINE input file from the current Mechanical APDL model.
ANSTOASAS - Creates an ASAS input file from the current ANSYS model.
ANTIME - Generates a sequential contour animation over a range of time.
ANTYPE - Specifies the analysis type and restart status.
/ANUM - Specifies the annotation number, type, and hot spot (GUI).
AOFFST - Generates an area, offset from a given area.
AOVLAP - Overlaps areas.
APLOT - Displays the selected areas.
APORT - Specifies input data for plane wave and acoustic duct ports.
APPEND - Reads data from the results file and appends it to the database.
APTN - Partitions areas.
ARCLEN - Activates the arc-length method.
ARCTRM - Controls termination of the solution when the arc-length method is used.
AREAS - Specifies "Areas" as the subsequent status topic.
AREFINE - Refines the mesh around specified areas.
AREMESH - Generates an area in which to create a new mesh for rezoning.
AREVERSE - Reverses the normal of an area, regardless of its connectivity or mesh status.
AROTAT - Generates cylindrical areas by rotating a line pattern about an axis.
ARSCALE - Generates a scaled set of areas from a pattern of areas.
ARSYM - Generates areas from an area pattern by symmetry reflection.
ASBA - Subtracts areas from areas.
ASBL - Subtracts lines from areas.
ASBV - Subtracts volumes from areas.
ASBW - Subtracts the intersection of the working plane from areas (divides areas).
ASCRES - Specifies the output type for an acoustic scattering analysis.
ASEL - Selects a subset of areas.
ASIFILE - Writes or reads one-way acoustic-structural coupling data.
*ASK - Prompts the user to input a parameter value.
ASKIN - Generates an area by "skinning" a surface through guiding lines.
ASLL - Selects those areas containing the selected lines.
ASLV - Selects those areas contained in the selected volumes.
ASOL - Specifies the acoustic solver with scattered field formulation.
/ASSIGN - Reassigns a file name to an ANSYS file identifier.
ASUB - Generates an area using the shape of an existing area.
ASUM - Calculates and prints geometry statistics of the selected areas.
ATAN - Forms the arctangent of a complex variable.
ATRAN - Transfers a pattern of areas to another coordinate system.
ATYPE - Specifies "Analysis types" as the subsequent status topic.
/AUTO - Resets the focus and distance specifications to "automatically calculated."
AUTOTS - Specifies whether to use automatic time stepping or load stepping.
/AUX2 - Enters the binary file dumping processor.
/AUX3 - Enters the results file editing processor.
/AUX12 - Enters the radiation processor.
/AUX15 - Enters the IGES file transfer processor.
AVPRIN - Specifies how principal and vector sums are to be calculated.
AVRES - Specifies how results data will be averaged when PowerGraphics is enabled.
AWAVE - Specifies input data for an acoustic incident wave.
/AXLAB - Labels the X and Y axes on graph displays.
*AXPY - Performs the matrix operation M2= v*M1 + w*M2.
III. B Commands
/BATCH - Sets the program mode to "batch."
BCSOPTION - Sets memory option for the sparse solver.
BETAD - Defines the stiffness matrix multiplier for damping.
BF - Defines a nodal body force load.
BFA - Defines a body force load on an area.
BFADELE - Deletes body force loads on an area.
BFALIST - Lists the body force loads on an area.
BFCUM - Specifies that nodal body force loads are to be accumulated.
BFDELE - Deletes nodal body force loads.
BFE - Defines an element body force load.
BFECUM - Specifies whether to ignore subsequent element body force loads.
BFEDELE - Deletes element body force loads.
BFELIST - Lists the element body force loads.
BFESCAL - Scales element body force loads.
BFINT - Activates the body force interpolation operation.
BFK - Defines a body force load at a keypoint.
BFKDELE - Deletes body force loads at a keypoint.
BFKLIST - Lists the body force loads at keypoints.
BFL - Defines a body force load on a line.
BFLDELE - Deletes body force loads on a line.
BFLIST - Lists the body force loads on nodes.
BFLLIST - Lists the body force loads on a line.
BFSCALE - Scales body force loads at nodes.
BFTRAN - Transfers solid model body force loads to the finite element model.
BFUNIF - Assigns a uniform body force load to all nodes.
BFV - Defines a body force load on a volume.
BFVDELE - Deletes body force loads on a volume.
BFVLIST - Lists the body force loads on a volume.
BIOOPT - Specifies "Biot-Savart options" as the subsequent status topic.
BIOT - Calculates the Biot-Savart source magnetic field intensity.
BLC4 - Creates a rectangular area or block volume by corner points.
BLC5 - Creates a rectangular area or block volume by center and corner points.
BLOCK - Creates a block volume based on working plane coordinates.
BOOL - Specifies "Booleans" as the subsequent status topic.
BOPTN - Specifies Boolean operation options.
BSAX - Specifies the axial strain and axial force relationship for beam sections.
BSMD - Specifies mass per unit length for a nonlinear general beam section.
BSM1 - Specifies the bending curvature and moment relationship in plane XZ for beam sections.
BSM2 - Specifies the bending curvature and moment relationship in plane XY for beam sections.
BSPLIN - Generates a single line from a spline fit to a series of keypoints.
BSS1 - Specifies the transverse shear strain and force relationship in plane XZ for beam sections.
BSS2 - Specifies the transverse shear strain and force relationship in plane XY for beam sections.
BSTE - Specifies a thermal expansion coefficient for a nonlinear general beam section.
BSTQ - Specifies the cross section twist and torque relationship for beam sections.
BTOL - Specifies the Boolean operation tolerances.
BUCOPT - Specifies buckling analysis options.
IV. C Commands
C*** - Places a comment in the output.
CALC - Specifies "Calculation settings" as the subsequent status topic.
CAMPBELL - Prepares the result file for a subsequent Campbell diagram of a prestressed structure.
CBDOF - Activates cut-boundary interpolation (for submodeling).
CBMD - Specifies preintegrated section mass matrix for composite-beam sections.
CBMX - Specifies preintegrated cross-section stiffness for composite beam sections.
CBTE - Specifies a thermal expansion coefficient for a composite beam section.
CBTMP - Specifies a temperature for composite-beam input.
CDOPT - Specifies format to be used for archiving geometry.
CDREAD - Reads a file of solid model and database information into the database.
CDWRITE - Writes geometry and load database items to a file.
CE - Defines a constraint equation relating degrees of freedom.
CECHECK - Check constraint equations and couplings for rigid body motions.
CECMOD - Modifies the constant term of a constraint equation during solution.
CECYC - Generates the constraint equations for a cyclic symmetry analysis
CEDELE - Deletes constraint equations.
CEINTF - Generates constraint equations at an interface.
CELIST - Lists the constraint equations.
CENTER - Defines a node at the center of curvature of 2 or 3 nodes.
CEQN - Specifies "Constraint equations" as the subsequent status topic.
CERIG - Defines a rigid region.
CESGEN - Generates a set of constraint equations from existing sets.
CFACT - Defines complex scaling factors to be used with operations.
*CFCLOS - Closes the "command" file.
*CFOPEN - Opens a "command" file.
*CFWRITE - Writes a Mechanical APDL command (or similar string) to a "command" file.
/CFORMAT - Controls the graphical display of alphanumeric character strings for parameters, components, assemblies, and tables.
CGLOC - Specifies the origin location of the acceleration coordinate system.
CGOMGA - Specifies the rotational velocity of the global origin.
CGROW - Defines crack-growth information
CHECK - Checks current database items for completeness.
CHKMSH - Checks area and volume entities for previous meshes.
CINT - Defines parameters associated with fracture parameter calculations
CIRCLE - Generates circular arc lines.
CISOL - Stores fracture parameter information in a variable.
/CLABEL - Specifies contour labeling.
/CLEAR - Clears the database.
CLOCAL - Defines a local coordinate system relative to the active coordinate system.
CLOG - Forms the common log of a variable
/CLOG - Copies the session log file to a named file.
CLRMSHLN - Clears meshed entities.
CM - Groups geometry items into a component.
CMACEL - Specifies the translational acceleration of an element component
/CMAP - Changes an existing or creates a new color mapping table.
CMATRIX - Performs electrostatic field solutions and calculates the self and mutual capacitances between multiple conductors.
CMDELE - Deletes a component or assembly definition.
CMDOMEGA - Specifies the rotational acceleration of an element component about a user-defined rotational axis.
CMEDIT - Edits an existing assembly.
CMGRP - Groups components and assemblies into an assembly.
CMLIST - Lists the contents of a component or assembly.
CMMOD - Modifies the specification of a component.
CMOMEGA - Specifies the rotational velocity of an element component about a user-defined rotational axis.
CMPLOT - Plots the entities contained in a component or assembly.
CMROTATE - Specifies the rotational velocity of an element component in a brake squeal analysis.
CMSEL - Selects a subset of components and assemblies.
CMSFILE - Specifies a list of component mode synthesis (CMS) results files for plotting results on the assembly.
CMSOPT - Specifies component mode synthesis (CMS) analysis options.
CMWRITE - Writes node and element components and assemblies to a file.
CNCHECK - Provides and/or adjusts the initial status of contact pairs.
CNKMOD - Modifies contact element key options.
CNTR - Redirects contact pair output quantities to a text file.
CNVTOL - Sets convergence values for nonlinear analyses.
/COLOR - Specifies the color mapping for various items.
/COM - Places a comment in the output.
*COMP - Compresses a matrix using a specified algorithm.
COMBINE - Combines distributed memory parallel (Distributed ANSYS) files.
COMPRESS - Deletes all specified sets.
CON4 - Creates a conical volume anywhere on the working plane.
CONE - Creates a conical volume centered about the working plane origin.
/CONFIG - Assigns values to ANSYS configuration parameters.
CONJUG - Forms the complex conjugate of a variable.
/CONTOUR - Specifies the uniform contour values on stress displays.
/COPY - Copies a file.
CORIOLIS - Applies the Coriolis effect to a rotating structure.
COUPLE - Specifies "Node coupling" as the subsequent status topic.
COVAL - Defines PSD cospectral values.
CP - Defines (or modifies) a set of coupled degrees of freedom.
CPCYC - Couples the two side faces of a cyclically symmetric model for loadings that are the same on every segment.
CPDELE - Deletes coupled degree of freedom sets.
CPINTF - Defines coupled degrees of freedom at an interface.
/CPLANE - Specifies the cutting plane for section and capped displays.
CPLGEN - Generates sets of coupled nodes from an existing set.
CPLIST - Lists the coupled degree of freedom sets.
CPMERGE - Merges different couple sets with duplicate degrees of freedom into one couple set.
CPNGEN - Defines, modifies, or adds to a set of coupled degrees of freedom.
CPSGEN - Generates sets of coupled nodes from existing sets.
CQC - Specifies the complete quadratic mode combination method.
*CREATE - Opens (creates) a macro file.
CRPLIM - Specifies the creep criterion for automatic time stepping.
CS - Defines a local coordinate system by three node locations.
CSCIR - Locates the singularity for non-Cartesian local coordinate systems.
CSDELE - Deletes local coordinate systems.
CSKP - Defines a local coordinate system by three keypoint locations.
CSLIST - Lists coordinate systems.
CSWPLA - Defines a local coordinate system at the origin of the working plane.
CSYS - Activates a previously defined coordinate system.
/CTYPE - Specifies the type of contour display.
CURR2D - Calculates current flow in a 2-D conductor.
CUTCONTROL - Controls time-step cutback during a nonlinear solution.
/CVAL - Specifies nonuniform contour values on stress displays.
CVAR - Computes covariance between two quantities.
/CWD - Changes the current working directory.
CYCCALC - Calculates results from a cyclic harmonic mode-superposition analysis using the specifications defined by CYCSPEC.
/CYCEXPAND - Graphically expands displacements, stresses and strains of a cyclically symmetric model.
CYCFILES - Specifies the data files where results are to be found for a cyclic symmetry mode-superposition harmonic analysis.
CYCFREQ - Specifies solution options for a cyclic symmetry mode-superposition harmonic analysis.
*CYCLE - Bypasses commands within a do-loop.
CYCLIC - Specifies a cyclic symmetry analysis.
CYCOPT - Specifies solution options for a cyclic symmetry analysis.
CYCPHASE - Provides tools for determining minimum and maximum possible result values from frequency couplets produced in a modal cyclic symmetry analysis.
CYCSPEC - Defines the set of result items for a subsequent CYCCALC command in postprocessing a cyclic harmonic mode-superposition analysis.
CYL4 - Creates a circular area or cylindrical volume anywhere on the working plane.
CYL5 - Creates a circular area or cylindrical volume by end points.
CYLIND - Creates a cylindrical volume centered about the working plane origin.
CZDEL - Edits or clears cohesive zone sections.
CZMESH - Create and mesh an interface area composed of cohesive zone elements.
V. D Commands
D - Defines degree-of-freedom constraints at nodes.
DA - Defines degree-of-freedom constraints on areas.
DADELE - Deletes degree-of-freedom constraints on an area.
DALIST - Lists the DOF constraints on an area.
DAMORPH - Move nodes in selected areas to conform to structural displacements.
DATA - Reads data records from a file into a variable.
DATADEF - Specifies "Directly defined data status" as the subsequent status topic.
DCGOMG - Specifies the rotational acceleration of the global origin.
DCUM - Specifies that DOF constraint values are to be accumulated.
DCVSWP - Performs a DC voltage sweep on a ROM element.
DDASPEC - Specifies the shock spectrum computation constants for DDAM analysis.
DDELE - Deletes degree-of-freedom constraints.
DDOPTION - Sets domain decomposer option for Distributed ANSYS.
DEACT - Specifies "Element birth and death" as the subsequent status topic.
DEFINE - Specifies "Data definition settings" as the subsequent status topic.
*DEL - Deletes a parameter or parameters (GUI).
DELETE - Specifies sets in the results file to be deleted before postprocessing.
/DELETE - Deletes a file.
DELTIM - Specifies the time step sizes to be used for the current load step.
DEMORPH - Move nodes in selected elements to conform to structural displacements.
DERIV - Differentiates a variable.
DESIZE - Controls default element sizes.
DESOL - Defines or modifies solution results at a node of an element.
DETAB - Modifies element table results in the database.
/DEVDISP - Controls graphics device options.
/DEVICE - Controls graphics device options.
/DFLAB - Changes degree-of-freedom labels for user custom elements.
DFLX - Imposes a uniform magnetic flux B on an edge-element electromagnetic model.
DFSWAVE - Specifies the incident planar waves with random phases for a diffuse sound field.
DIG - Digitizes nodes to a surface.
DIGIT - Specifies "Node digitizing" as the subsequent status topic.
*DIM - Defines an array parameter and its dimensions.
/DIRECTORY - Put the file names in the current directory into a string parameter array.
DISPLAY - Specifies "Display settings" as the subsequent status topic.
/DIST - Specifies the viewing distance for magnifications and perspective.
DJ - Specifies boundary conditions on the components of relative motion of a joint element.
DJDELE - Deletes boundary conditions on the components of relative motion of a joint element.
DJLIST - Lists boundary conditions applied to joint elements.
DK - Defines DOF constraints at keypoints.
DKDELE - Deletes DOF constraints at a keypoint.
DKLIST - Lists the DOF constraints at keypoints.
DL - Defines DOF constraints on lines.
DLDELE - Deletes DOF constraints on a line.
DLIST - Lists DOF constraints.
DLLIST - Lists DOF constraints on a line.
*DMAT - Creates a dense matrix.
DMOVE - Digitizes nodes on surfaces and along intersections.
DMPEXT - Extracts modal damping coefficients in a specified frequency range.
DMPOPTION - Specifies distributed memory parallel (Distributed ANSYS) file combination options.
DMPRAT - Sets a constant modal damping ratio.
DMPSTR - Sets a constant structural damping coefficient.
DNSOL - Defines or modifies solution results at a node.
*DO - Defines the beginning of a do-loop.
DOF - Adds degrees of freedom to the current DOF set.
DOFSEL - Selects a DOF label set for reference by other commands.
DOMEGA - Specifies the rotational acceleration of the structure.
*DOT - Computes the dot (or inner) product of two vectors.
*DOWHILE - Loops repeatedly through the next *ENDDO command.
DSCALE - Scales DOF constraint values.
/DSCALE - Sets the displacement multiplier for displacement displays.
DSET - Sets the scale and drawing plane orientation for a digitizing tablet.
DSPOPTION - Sets memory option for the distributed sparse solver.
DSUM - Specifies the double sum mode combination method.
DSURF - Defines the surface upon which digitized nodes lie.
DSYM - Specifies symmetry or antisymmetry degree-of-freedom constraints on nodes.
DSYS - Activates a display coordinate system for geometry listings and plots.
DTRAN - Transfers solid model DOF constraints to the finite element model.
DUMP - Dumps the contents of a binary file.
/DV3D - Sets 3-D device option modes.
DVAL - Defines values at enforced motion base.
DVMORPH - Move nodes in selected volumes to conform to structural displacements.
DYNOPT - Specifies "Dynamic analysis options" as the subsequent status topic.
VI. E Commands
E - Defines an element by node connectivity.
EALIVE - Reactivates an element (for the birth and death capability).
ECPCHG - Optimizes degree-of-freedom usage in a coupled acoustic model.
EDADAPT - Activates adaptive meshing in an explicit dynamic analysis.
EDALE - Assigns mesh smoothing to explicit dynamic elements that use the ALE formulation.
EDASMP - Creates a part assembly to be used in an explicit dynamic analysis.
EDBOUND - Defines a boundary plane for sliding or cyclic symmetry.
EDBX - Creates a box shaped volume to be used in a contact definition for explicit dynamics.
EDBVIS - Specifies global bulk viscosity coefficients for an explicit dynamics analysis.
EDCADAPT - Specifies adaptive meshing controls for an explicit dynamic analysis.
EDCGEN - Specifies contact parameters for an explicit dynamics analysis.
EDCLIST - Lists contact entity specifications in an explicit dynamics analysis.
EDCMORE - Specifies additional contact parameters for a given contact definition in an explicit dynamic analysis.
EDCNSTR - Defines various types of constraints for an explicit dynamic analysis.
EDCONTACT - Specifies contact surface controls for an explicit dynamics analysis.
EDCPU - Specifies CPU time limit for an explicit dynamics analysis.
EDCRB - Constrains two rigid bodies to act as one in an explicit dynamics analysis.
EDCSC - Specifies whether to use subcycling in an explicit dynamics analysis.
EDCTS - Specifies mass scaling and scale factor of computed time step for an explicit dynamics analysis.
EDCURVE - Specifies data curves for an explicit dynamic analysis.
EDDAMP - Defines mass weighted (Alpha) or stiffness weighted (Beta) damping for an explicit dynamics model.
EDDBL - Selects a numerical precision type of the explicit dynamics analysis.
EDDC - Deletes or deactivates/reactivates contact surface specifications in an explicit dynamic analysis.
EDDRELAX - Activates initialization to a prescribed geometry or dynamic relaxation for the explicit analysis.
EDDUMP - Specifies output frequency for the explicit dynamic restart file (d3dump).
EDELE - Deletes selected elements from the model.
EDENERGY - Specifies energy dissipation controls for an explicit dynamics analysis.
EDFPLOT - Allows plotting of explicit dynamics forces and other load symbols.
EDGCALE - Defines global ALE controls for an explicit dynamic analysis.
/EDGE - Displays only the common lines (“edges”) of an object.
EDHGLS - Specifies the hourglass coefficient for an explicit dynamics analysis.
EDHIST - Specifies time-history output for an explicit dynamic analysis.
EDHTIME - Specifies the time-history output interval for an explicit dynamics analysis.
EDINT - Specifies number of integration points for explicit shell and beam output.
EDIPART - Defines inertia for rigid parts in an explicit dynamics analysis.
EDIS - Specifies stress initialization in an explicit dynamic full restart analysis.
EDLCS - Defines a local coordinate system for use in explicit dynamics analysis.
EDLOAD - Specifies loads for an explicit dynamics analysis.
EDMP - Defines material properties for an explicit dynamics analysis.
EDNB - Defines a nonreflecting boundary in an explicit dynamic analysis.
EDNDTSD - Allows smoothing of noisy data for explicit dynamics analyses and provides a graphical representation of the data.
EDNROT - Applies a rotated coordinate nodal constraint in an explicit dynamics analysis.
EDOPT - Specifies the type of output for an explicit dynamics analysis.
EDOUT - Specifies time-history output (ASCII format) for an explicit dynamics analysis.
EDPART - Configures parts for an explicit dynamics analysis.
EDPC - Selects and plots explicit dynamic contact entities.
EDPL - Plots a time dependent load curve in an explicit dynamic analysis.
EDPVEL - Applies initial velocities to parts or part assemblies in an explicit dynamic analysis.
EDRC - Specifies rigid/deformable switch controls in an explicit dynamic analysis.
EDRD - Switches a part from deformable to rigid or from rigid to deformable in an explicit dynamic analysis.
EDREAD - Reads explicit dynamics output into variables for time-history postprocessing.
EDRI - Defines inertia properties for a new rigid body that is created when a deformable part is switched to rigid in an explicit dynamic analysis.
EDRST - Specifies the output interval for an explicit dynamic analysis.
EDRUN - Specify LS-DYNA serial or parallel processing.
EDSHELL - Specifies shell computation controls for an explicit dynamics analysis.
EDSOLV - Specifies "explicit dynamics solution" as the subsequent status topic.
EDSP - Specifies small penetration checking for contact entities in an explicit dynamic analysis.
EDSTART - Specifies status (new or restart) of an explicit dynamics analysis.
EDTERM - Specifies termination criteria for an explicit dynamic analysis.
EDTP - Plots explicit elements based on their time step size.
EDVEL - Applies initial velocities to nodes or node components in an explicit dynamic analysis.
EDWELD - Defines a massless spotweld or generalized weld for use in an explicit dynamic analysis.
EDWRITE - Writes explicit dynamics input to an LS-DYNA input file.
EEXTRUDE - Extrudes 2-D plane elements into 3-D solids during a 2-D to 3-D analysis.
/EFACET - Specifies the number of facets per element edge for PowerGraphics displays.
EGEN - Generates elements from an existing pattern.
*EIGEN - Performs a modal solution with unsymmetric or damping matrices.
EINFIN - Generates structural infinite elements from selected nodes.
EINTF - Defines two-node elements between coincident or offset nodes.
EKILL - Deactivates an element (for the birth and death capability).
ELBOW - Specifies degrees of freedom to be coupled for end release and applies section constraints to elbow elements.
ELEM - Specifies "Elements" as the subsequent status topic.
ELIST - Lists the elements and their attributes.
*ELSE - Separates the final if-then-else block.
*ELSEIF - Separates an intermediate if-then-else block.
EMAGERR - Calculates the relative error in an electrostatic or electromagnetic field analysis.
EMATWRITE - Forces the writing of all the element matrices to File.EMAT.
EMF - Calculates the electromotive force (emf), or voltage drop along a predefined path.
EMFT - Summarizes electromagnetic forces and torques.
EMID - Adds or removes midside nodes.
EMIS - Specifies emissivity as a material property for the Radiation Matrix method.
EMODIF - Modifies a previously defined element.
EMORE - Adds more nodes to the just-defined element.
EMSYM - Specifies circular symmetry for electromagnetic sources.
EMTGEN - Generates a set of TRANS126 elements.
EMUNIT - Specifies the system of units for magnetic field problems.
EN - Defines an element by its number and node connectivity.
*END - Closes a macro file.
*ENDDO - Ends a do-loop and starts the looping action.
*ENDIF - Ends an if-then-else.
ENDRELEASE - Specifies degrees of freedom to be decoupled for end release.
ENERSOL - Specifies the total energies to be stored.
ENGEN - Generates elements from an existing pattern.
ENORM - Reorients shell element normals or line element node connectivity.
ENSYM - Generates elements by symmetry reflection.
/EOF - Exits the file being read.
EORIENT - Reorients solid element normals.
EPLOT - Produces an element display.
EQSLV - Specifies the type of equation solver.
ERASE - Explicitly erases the current display.
/ERASE - Specifies that the screen is to be erased before each display.
EREAD - Reads elements from a file.
EREFINE - Refines the mesh around specified elements.
EREINF - Generates reinforcing elements from selected existing (base) elements.
ERESX - Specifies extrapolation of integration point results.
ERNORM - Controls error estimation calculations.
ERRANG - Specifies the element range to be read from a file.
ESCHECK - Perform element shape checking for a selected element set.
ESEL - Selects a subset of elements.
/ESHAPE - Displays elements with shapes determined from the real constants, section definition, or other inputs.
ESIZE - Specifies the default number of line divisions.
ESLA - Selects those elements associated with the selected areas.
ESLL - Selects those elements associated with the selected lines.
ESLN - Selects those elements attached to the selected nodes.
ESLV - Selects elements associated with the selected volumes.
ESOL - Specifies element data to be stored from the results file.
ESORT - Sorts the element table.
ESSOLV - Performs a coupled electrostatic-structural analysis.
ESTIF - Specifies the matrix multiplier for deactivated elements.
ESURF - Generates elements overlaid on the free faces of selected nodes.
ESYM - Generates elements from a pattern by a symmetry reflection.
ESYS - Sets the element coordinate system attribute pointer.
ET - Defines a local element type from the element library.
ETABLE - Fills a table of element values for further processing.
ETCHG - Changes element types to their corresponding types.
ETCONTROL - Control the element technologies used in element formulation (for applicable elements).
ETDELE - Deletes element types.
ETLIST - Lists currently defined element types.
ETYPE - Specifies "Element types" as the subsequent status topic.
EUSORT - Restores original order of the element table.
EWRITE - Writes elements to a file.
EXBOPT - Specifies file output options in a CMS generation pass.
*EXIT - Exits a do-loop.
/EXIT - Stops the run and returns control to the system.
EXOPTION - Specifies the EXPROFILE options for the Mechanical APDL to ANSYS CFX profile file transfer.
EXP - Forms the exponential of a variable.
EXPAND - Displays the results of a modal cyclic symmetry analysis.
/EXPAND - Allows the creation of a larger graphic display than represented by the actual finite element analysis model.
EXPASS - Specifies an expansion pass of an analysis.
*EXPORT - Exports a matrix to a file in the specified format.
EXPROFILE - Exports Mechanical APDL interface data on selected nodes to an ANSYS CFX Profile file.
EXPSOL - Specifies the solution to be expanded for mode-superposition analyses or substructure analyses.
EXTOPT - Controls options relating to the generation of volume elements from area elements.
EXTREM - Lists the extreme values for variables.
EXUNIT - Specifies the interface data unit labels to be written to the profile file from Mechanical APDL to ANSYS CFX transfer.
VII. F Commands
F - Specifies force loads at nodes.
/FACET - Specifies the facet representation used to form solid model displays.
FC - Provides failure criteria information and activates a data table to input temperature-dependent stress and strain limits.
FCCHECK - Checks both the strain and stress input criteria for all materials.
FCDELE - Deletes previously defined failure criterion data for the given material.
FCLIST - To list what the failure criteria is that you have input.
/FCOMP - Specifies file compression level.
FCUM - Specifies that force loads are to be accumulated.
FCTYP - Activates or removes failure-criteria types for postprocessing.
FDELE - Deletes force loads on nodes.
/FDELE - Deletes a binary file after it is used.
FEBODY - Specifies "Body loads on elements" as the subsequent status topic.
FECONS - Specifies "Constraints on nodes" as the subsequent status topic.
FEFOR - Specifies "Forces on nodes" as the subsequent status topic.
FESURF - Specifies "Surface loads on elements" as the subsequent status topic.
*FFT - Computes the fast Fourier transformation of a specified matrix or vector.
FILE - Specifies the data file where results are to be found.
FILEAUX2 - Specifies the binary file to be dumped.
FILEAUX3 - Specifies the results file to be edited.
FILEDISP - Specifies the file containing the graphics data.
FILL - Generates a line of nodes between two existing nodes.
FILLDATA - Fills a variable by a ramp function.
/FILNAME - Changes the Jobname for the analysis.
FINISH - Exits normally from a processor.
FITEM - Identifies items chosen by a picking operation (GUI).
FJ - Specify forces or moments on the components of the relative motion of a joint element.
FJDELE - Deletes forces (or moments) on the components of the relative motion of a joint element.
FJLIST - Lists forces and moments applied on joint elements.
FK - Defines force loads at keypoints.
FKDELE - Deletes force loads at a keypoint.
FKLIST - Lists the forces at keypoints.
FLIST - Lists force loads on the nodes.
FLST - Specifies data required for a picking operation (GUI).
FLUXV - Calculates the flux passing through a closed contour.
FLUREAD - Reads one-way Fluent-to-Mechanical APDL coupling data via a .cgns file with one-side fast Fourier transformation complex pressure peak value.
/FOCUS - Specifies the focus point (center of the window).
FORCE - Selects the element nodal force type for output.
FORM - Specifies the format of the file dump.
/FORMAT - Specifies format controls for tables.
*FREE - Deletes a matrix or a solver object and frees its memory allocation.
FREQ - Defines the frequency points for the SV vs. FREQ tables.
FRQSCL - Turns on automatic scaling of the entire mass matrix and frequency range for modal analyses.
FSCALE - Scales force load values in the database.
FSSECT - Calculates and stores total linearized stress components.
FSSPARM - Calculates reflection and transmission properties of a frequency selective surface.
FSUM - Sums the nodal force and moment contributions of elements.
FTRAN - Transfers solid model forces to the finite element model.
FTYPE - Specifies the file type and pressure type for the subsequent import of source points and pressures.
FVMESH - Generates nodes and tetrahedral volume elements from detached exterior area elements (facets).
VIII. G Commands
GAP - Specifies "mode-superposition transient gap conditions" as the subsequent status topic.
GAPF - Defines the gap force data to be stored in a variable.
GAUGE - Gauges the problem domain for a magnetic edge-element formulation.
GCDEF - Defines interface interactions between general contact surfaces.
GCGEN - Creates contact elements for general contact.
/GCMD - Controls the type of element or graph display used for the GPLOT command.
/GCOLUMN - Allows the user to apply a label to a specified curve.
GENOPT - Specifies "General options" as the subsequent status topic.
GEOM - Defines the geometry specifications for the radiation matrix calculation.
GEOMETRY - Specifies "Geometry" as the subsequent status topic.
*GET - Retrieves a value and stores it as a scalar parameter or part of an array parameter.
/GFILE - Specifies the pixel resolution on Z-buffered graphics files.
/GFORMAT - Specifies the format for the graphical display of numbers.
/GLINE - Specifies the element outline style.
/GMARKER - Specifies the curve marking style.
GMATRIX - Performs electric field solutions and calculates the self and mutual conductance between multiple conductors.
GMFACE - Specifies the facet representation used to form solid models.
*GO - Causes a specified line on the input file to be read next.
/GO - Reactivates suppressed printout.
/GOLIST - Reactivates the suppressed data input listing.
/GOPR - Reactivates suppressed printout.
GP - Defines a gap condition for transient analyses.
GPDELE - Deletes gap conditions.
GPLIST - Lists the gap conditions.
GPLOT - Controls general plotting.
/GRAPHICS - Defines the type of graphics display.
/GRESUME - Sets graphics settings to the settings on a file.
/GRID - Selects the type of grid on graph displays.
/GROPT - Sets various line graph display options.
GRP - Specifies the grouping mode combination method.
/GRTYP - Selects single or multiple Y-axes graph displays.
/GSAVE - Saves graphics settings to a file for later use.
GSBDATA - Specifies the constraints or applies the load at the ending point for generalized plane strain option.
GSGDATA - Specifies the reference point and defines the geometry in the fiber direction for the generalized plane strain element option.
GSLIST - When using generalized plane strain, lists the input data or solutions.
GSSOL - Specifies which results to store from the results file when using generalized plane strain.
/GST - Turns Graphical Solution Tracking (GST) on or off.
GSUM - Calculates and prints geometry items.
/GTHK - Sets line thicknesses for graph lines.
/GTYPE - Controls the entities that the GPLOT command displays.
IX. H Commands
HARFRQ - Defines the frequency range in a harmonic analysis.
/HBC - Determines how boundary condition symbols are displayed in a display window.
HBMAT - Writes an assembled global matrix in Harwell-Boeing format.
/HEADER - Sets page and table heading print controls.
HELP - Displays help information on ANSYS commands and element types.
HELPDISP - Displays help information on DISPLAY program commands.
HEMIOPT - Specifies options for Hemicube view factor calculation.
HFANG - Defines or displays spatial angles of a spherical radiation surface for sound radiation parameter calculations.
HFSYM - Indicates the presence of symmetry planes for the computation of acoustic fields in the near and far field domains (beyond the finite element region).
HPGL - Specifies various HP options.
HPTCREATE - Defines a hard point.
HPTDELETE - Deletes selected hardpoints.
HRCPLX - Computes and stores in the database the time-harmonic solution at a prescribed phase angle.
HREXP - Specifies the phase angle for the harmonic analysis expansion pass.
HROPT - Specifies harmonic analysis options.
HROCEAN - Perform the harmonic ocean wave procedure (HOWP).
HROUT - Specifies the harmonic analysis output options.
X. I Commands
IC - Specifies initial conditions at nodes.
ICDELE - Deletes initial conditions at nodes.
ICLIST - Lists the initial conditions.
/ICLWID - Scales the line width of circuit builder icons.
ICROTATE - Specifies initial velocity at nodes as a sum of rotation about an axis and translation.
/ICSCALE - Scales the icon size for elements supported in the circuit builder.
*IF - Conditionally causes commands to be read.
IGESIN - Transfers IGES data from a file into ANSYS.
IGESOUT - Writes solid model data to a file in IGES Version 5.1 format.
/IMAGE - Allows graphics data to be captured and saved.
IMAGIN - Forms an imaginary variable from a complex variable.
IMESH - Generates nodes and interface elements along lines or areas.
IMMED - Allows immediate display of a model as it is generated.
INISTATE - Defines initial state data and parameters.
*INIT - Initializes a vector or matrix.
/INPUT - Switches the input file for the commands that follow.
/INQUIRE - Returns system information to a parameter.
INRES - Identifies the data to be retrieved from the results file.
INRTIA - Specifies "Inertial loads" as the subsequent status topic.
INT1 - Integrates a variable.
INTSRF - Integrates nodal results on an exterior surface.
IOPTN - Controls options relating to importing a model.
IRLF - Specifies that inertia relief calculations are to be performed.
IRLIST - Prints inertia relief summary table.
*ITENGINE - Performs a solution using an iterative solver.
XI. J Commands
JPEG - Provides JPEG file export for ANSYS displays.
JSOL - Specifies result items to be stored for the joint element.
XII. K Commands
K - Defines a keypoint.
KATT - Associates attributes with the selected, unmeshed keypoints.
KBC - Specifies ramped or stepped loading within a load step.
KBETW - Creates a keypoint between two existing keypoints.
KCALC - Calculates stress intensity factors in fracture mechanics analyses.
KCENTER - Creates a keypoint at the center of a circular arc defined by three locations.
KCLEAR - Deletes nodes and point elements associated with selected keypoints.
KDELE - Deletes unmeshed keypoints.
KDIST - Calculates and lists the distance between two keypoints.
KEEP - Stores POST26 definitions and data during active session.
KESIZE - Specifies the edge lengths of the elements nearest a keypoint.
KEYOPT - Sets element key options.
KEYPTS - Specifies "Keypoints" as the subsequent status topic.
KEYW - Sets a keyword used by the GUI for context filtering (GUI).
KFILL - Generates keypoints between two keypoints.
KGEN - Generates additional keypoints from a pattern of keypoints.
KL - Generates a keypoint at a specified location on an existing line.
KLIST - Lists the defined keypoints or hard points.
KMESH - Generates nodes and point elements at keypoints.
KMODIF - Modifies an existing keypoint.
KMOVE - Calculates and moves a keypoint to an intersection.
KNODE - Defines a keypoint at an existing node location.
KPLOT - Displays the selected keypoints.
KPSCALE - Generates a scaled set of (meshed) keypoints from a pattern of keypoints.
KREFINE - Refines the mesh around specified keypoints.
KSCALE - Generates a scaled pattern of keypoints from a given keypoint pattern.
KSCON - Specifies a keypoint about which an area mesh will be skewed.
KSEL - Selects a subset of keypoints or hard points.
KSLL - Selects those keypoints contained in the selected lines.
KSLN - Selects those keypoints associated with the selected nodes.
KSUM - Calculates and prints geometry statistics of the selected keypoints.
KSYMM - Generates a reflected set of keypoints.
KTRAN - Transfers a pattern of keypoints to another coordinate system.
KUSE - Specifies whether or not to reuse the factorized matrix.
KWPAVE - Moves the working plane origin to the average location of keypoints.
KWPLAN - Defines the working plane using three keypoints.
XIII. L Commands
L - Defines a line between two keypoints.
L2ANG - Generates a line at an angle with two existing lines.
L2TAN - Generates a line tangent to two lines.
LANBOPTION - Specifies Block Lanczos eigensolver options.
LANG - Generates a straight line at an angle with a line.
LARC - Defines a circular arc.
/LARC - Creates annotation arcs (GUI).
LAREA - Generates the shortest line between two keypoints on an area.
LARGE - Finds the largest (the envelope) of three variables.
LATT - Associates element attributes with the selected, unmeshed lines.
LAYER - Specifies the element layer for which data are to be processed.
LAYERP26 - Specifies the element layer for which data are to be stored.
LAYLIST - Lists real constants material properties for layered elements.
LAYPLOT - Displays the layer stacking sequence for layered elements.
LCABS - Specifies absolute values for load case operations.
LCASE - Reads a load case into the database.
LCCALC - Specifies "Load case settings" as the subsequent status topic.
LCCAT - Concatenates multiple lines into one line for mapped meshing.
LCDEF - Creates a load case from a set of results on a results file.
LCFACT - Defines scale factors for load case operations.
LCFILE - Creates a load case from an existing load case file.
LCLEAR - Deletes nodes and line elements associated with selected lines.
LCOMB - Combines adjacent lines into one line.
LCOPER - Performs load case operations.
LCSEL - Selects a subset of load cases.
LCSL - Divides intersecting lines at their point(s) of intersection.
LCSUM - Specifies whether to process non-summable items in load case operations.
LCWRITE - Creates a load case by writing results to a load case file.
LCZERO - Zeroes the results portion of the database.
LDELE - Deletes unmeshed lines.
LDIV - Divides a single line into two or more lines.
LDRAG - Generates lines by sweeping a keypoint pattern along path.
LDREAD - Reads results from the results file and applies them as loads.
LESIZE - Specifies the divisions and spacing ratio on unmeshed lines.
LEXTND - Extends a line at one end by using its slope.
LFILLT - Generates a fillet line between two intersecting lines.
LFSURF - Generates surface elements overlaid on the edge of existing solid elements and assigns the extra node as the closest fluid element node.
LGEN - Generates additional lines from a pattern of lines.
LGLUE - Generates new lines by "gluing" lines.
LGWRITE - Writes the database command log to a file.
/LIGHT - Specifies the light direction for the display window.
LINA - Finds the intersection of a line with an area.
LINE - Specifies "Lines" as the subsequent status topic.
/LINE - Creates annotation lines (GUI).
LINES - Specifies the length of a printed page.
LINL - Finds the common intersection of lines.
LINP - Finds the pairwise intersection of lines.
LINV - Finds the intersection of a line with a volume.
LIST - Lists out the sets in the results file.
*LIST - Displays the contents of an external, coded file.
LLIST - Lists the defined lines.
LMESH - Generates nodes and line elements along lines.
LNSRCH - Activates a line search to be used with Newton-Raphson.
LOCAL - Defines a local coordinate system by a location and orientation.
LOVLAP - Overlaps lines.
LPLOT - Displays the selected lines.
LPTN - Partitions lines.
LREFINE - Refines the mesh around specified lines.
LREVERSE - Reverses the normal of a line, regardless of its connectivity or mesh status.
LROTAT - Generates circular lines by rotating a keypoint pattern about an axis.
LSBA - Subtracts areas from lines.
*LSBAC - Performs the solve (forward/backward substitution) of a factorized linear system.
LSBL - Subtracts lines from lines.
LSBV - Subtracts volumes from lines.
LSBW - Subtracts the intersection of the working plane from lines (divides lines).
LSCLEAR - Clears loads and load step options from the database.
LSDELE - Deletes load step files.
*LSDUMP - Dumps a linear solver engine to a binary File.
LSEL - Selects a subset of lines.
*LSENGINE - Creates a linear solver engine.
*LSFACTOR - Performs the numerical factorization of a linear solver system.
LSLA - Selects those lines contained in the selected areas.
LSLK - Selects those lines containing the selected keypoints.
LSOPER - Specifies "Load step operations" as the subsequent status topic.
/LSPEC - Specifies annotation line attributes (GUI).
LSREAD - Reads load and load step option data into the database.
*LSRESTORE - Restores a linear solver engine from a binary file.
LSSCALE - Generates a scaled set of lines from a pattern of lines.
LSSOLVE - Reads and solves multiple load steps.
LSTR - Defines a straight line irrespective of the active coordinate system.
LSUM - Calculates and prints geometry statistics of the selected lines.
LSWRITE - Writes load and load step option data to a file.
/LSYMBOL - Creates annotation symbols (GUI).
LSYMM - Generates lines from a line pattern by symmetry reflection.
LTAN - Generates a line at the end of, and tangent to, an existing line.
LTRAN - Transfers a pattern of lines to another coordinate system.
LUMPM - Specifies a lumped mass matrix formulation.
LVSCALE - Scales the load vector for mode-superposition analyses.
LWPLAN - Defines the working plane normal to a location on a line.
XIV. M Commands
M - Defines master degrees of freedom for superelement generation analyses.
MAGOPT - Specifies options for a 3-D magnetostatic field analysis.
MAGSOLV - Specifies magnetic solution options and initiates the solution.
/MAIL - Mails file to the specified address.
MAP - Maps pressures from source points to target surface elements.
/MAP - Enters the mapping processor.
MAP2DTO3D - Initiates a 2-D to 3-D analysis and maps variables.
MAPSOLVE - Maps solved node and element solutions from an original mesh to a new mesh.
MAPVAR - Defines tensors and vectors in user-defined state variables for rezoning and in 2-D to 3-D analyses.
MASCALE - Activates scaling of the entire system matrix.
MASTER - Specifies "Master DOF" as the subsequent status topic.
MAT - Sets the element material attribute pointer.
MATER - Specifies "Material properties" as the subsequent status topic.
MCHECK - Checks mesh connectivity.
MDAMP - Defines the damping ratios as a function of mode.
MDELE - Deletes master degrees of freedom.
MDPLOT - Plots frequency-dependent modal damping coefficients calculated by DMPEXT.
MEMM - Allows the current session to keep allocated memory
/MENU - Activates the Graphical User Interface (GUI).
*MERGE - Merges two dense matrices or vectors into one.
MESHING - Specifies "Meshing" as the subsequent status topic.
MFANALYSIS - Activates or deactivates an ANSYS Multi-field solver analysis.
MFBUCKET - Turns a bucket search on or off.
MFCALC - Specifies a calculation frequency for a field in an ANSYS Multi-field solver analysis.
MFCI - Sets the control parameters used by the conservative (CPP) interpolation scheme.
MFCLEAR - Deletes ANSYS Multi-field solver analysis settings.
MFCMMAND - Captures field solution options in a command file.
MFCONV - Sets convergence values for an ANSYS Multi-field solver analysis.
MFDTIME - Sets time step sizes for an ANSYS Multi-field solver analysis.
MFELEM - Defines a field by grouping element types.
MFEM - Add more element types to a previously defined field number.
MFEXTER - Defines external fields for an ANSYS Multi-field solver analysis.
MFFNAME - Specifies a file name for a field in an ANSYS Multi-field solver analysis.
MFFR - Setup Multi-Field relaxation factors for field solutions.
MFIMPORT - Imports a new field into a current ANSYS Multi-field solver analysis.
MFINTER - Specifies the interface load transfer interpolation option for an ANSYS Multi-field solver analysis.
MFITER - Sets the number of stagger iterations for an ANSYS Multi-field solver analysis.
MFLCOMM - Defines a load transfer for code coupling analyses.
MFLIST - Lists the settings for an ANSYS Multi-field solver analysis.
MFMAP - Calculates, saves, resumes, or deletes mapping data in an ANSYS Multi-field solver analysis.
MFORDER - Specifies field solution order for an ANSYS Multi-field solver analysis.
MFOUTPUT - Specifies results file output frequency for an ANSYS Multi-field solver analysis.
*MFOURI - Calculates the coefficients for, or evaluates, a Fourier series.
MFPSIMUL - Sets up a field solver group to simultaneously process with code coupling analyses.
MFRC - Controls file writing for multiframe restarts for the ANSYS Multi-field solver.
MFRELAX - Sets relaxation values for an ANSYS Multi-field solver analysis.
MFRSTART - Specifies restart status for an ANSYS Multi-field solver analysis.
MFSORDER - Sets up the solution sequence of simultaneous field solver groups for code coupling analyses.
MFSURFACE - Defines a surface load transfer for an ANSYS Multi-field solver analysis.
MFTIME - Sets end time for an ANSYS Multi-field solver analysis.
MFTOL - Activates or deactivates normal distance checking for surface mapping in an ANSYS Multi-field solver analysis.
*MFUN - Copies or transposes an array parameter matrix.
MFVOLUME - Defines a volume load transfer for an ANSYS Multi-field solver analysis.
MFWRITE - Writes an ANSYS master input file for MFX multiple code coupling.
MGEN - Generates additional MDOF from a previously defined set.
MIDTOL - Sets midstep residual criterion values for structural transient analyses.
/MKDIR - Creates a directory.
MLIST - Lists the MDOF of freedom.
MMASS - Specifies the missing mass response calculation.
MMF - Calculates the magnetomotive force along a path.
MODCONT - Specify additional modal analysis options.
MODDIR - Activates the remote read-only modal files usage.
MODE - Specifies the harmonic loading term for this load step.
MODIFY - Changes the listed values of the data in a set.
MODMSH - Controls the relationship of the solid model and the FE model.
MODSELOPTION - Specifies the criteria for selecting the modes to be expanded.
MODOPT - Specifies modal analysis options.
MONITOR - Controls contents of three variable fields in nonlinear solution monitor file.
*MOPER - Performs matrix operations on array parameter matrices.
MOPT - Specifies meshing options.
MORPH - Specifies morphing and remeshing controls.
MOVE - Calculates and moves a node to an intersection.
MP - Defines a linear material property as a constant or a function of temperature.
MPAMOD - Modifies temperature-dependent secant coefficients of thermal expansion.
MPCHG - Changes the material number attribute of an element.
MPCOPY - Copies linear material model data from one material reference number to another.
MPDATA - Defines property data to be associated with the temperature table.
MPDELE - Deletes linear material properties.
MPDRES - Reassembles existing material data with the temperature table.
/MPLIB - Sets the default material library read and write paths.
MPLIST - Lists linear material properties.
MPPLOT - Plots linear material properties as a function of temperature.
MPREAD - Reads a file containing material properties.
MPRINT - Specifies that radiation matrices are to be printed.
MPTEMP - Defines a temperature table for material properties.
MPTGEN - Adds temperatures to the temperature table by generation.
MPTRES - Restores a temperature table previously defined.
MPWRITE - Writes linear material properties in the database to a file (if the LIB option is not specified) or writes both linear and nonlinear material properties (if LIB is specified) from the database to a file.
/MREP - Enables you to reissue the graphics command macro "name" during a replot or zoom operation.
MRPM - Defines the revolutions per minute (RPM) for a machine rotation.
MSAVE - Sets the solver memory saving option. This option only applies to the PCG solver (including PCG Lanczos).
*MSG - Writes an output message via the ANSYS message subroutine.
MSHAPE - For elements that support multiple shapes, specifies the element shape to be used for meshing.
MSHCOPY - Simplifies the generation of meshes that have matching node element patterns on two different line groups (in 2-D) or area groups (3-D).
MSHKEY - Specifies whether free meshing or mapped meshing should be used to mesh a model.
MSHMID - Specifies placement of midside nodes.
MSHPATTERN - Specifies pattern to be used for mapped triangle meshing.
MSOLVE - Starts multiple solutions for an acoustic analysis.
/MSTART - Controls the initial GUI components.
MSTOLE - Adds two extra nodes from FLUID116 elements to SURF151 or SURF152 elements for convection analyses.
*MULT - Performs the matrix multiplication M3 = M1(T1)*M2(T2).
*MWRITE - Writes a matrix to a file in a formatted sequence.
MXPAND - Specifies the number of modes to expand and write for a modal or buckling analysis.
XV. N Commands
N - Defines a node.
NANG - Rotates a nodal coordinate system by direction cosines.
NAXIS - Generates nodes for general axisymmetric element sections.
NCNV - Sets the key to terminate an analysis.
NDELE - Deletes nodes.
NDIST - Calculates and lists the distance between two nodes.
NDSURF - Generates surface elements overlaid on the edge of existing elements and assigns the extra node as the closest fluid element node.
NEQIT - Specifies the maximum number of equilibrium iterations for nonlinear analyses.
/NERR - Limits the number of warning and error messages displayed.
NFORCE - Sums the nodal forces and moments of elements attached to nodes.
NGEN - Generates additional nodes from a pattern of nodes.
NKPT - Defines a node at an existing keypoint location.
NLADAPTIVE - Defines the criteria under which the mesh is refined or modified during a nonlinear solution.
NLDIAG - Sets nonlinear diagnostics functionality.
NLDPOST - Gets element component information from nonlinear diagnostic files.
NLGEOM - Includes large-deflection effects in a static or full transient analysis.
NLHIST - Specify result items to track during solution.
NLIST - Lists nodes.
NLMESH - Controls remeshing in nonlinear adaptivity.
NLOG - Forms the natural log of a variable.
NLOPT - Specifies "Nonlinear analysis options" as the subsequent status topic.
NMODIF - Modifies an existing node.
NOCOLOR - Removes color from graphics displays.
NODES - Specifies "Nodes" as the subsequent status topic.
/NOERASE - Prevents the screen erase between displays.
/NOLIST - Suppresses the data input listing.
NOOFFSET - Prevents the CDREAD command from offsetting specified data items
/NOPR - Suppresses the expanded interpreted input data listing.
NORA - Rotates nodal coordinate systems to surface normal
NORL - Rotates nodal coordinate systems perpendicular to line normal
/NORMAL - Allows displaying area elements by top or bottom faces.
NPLOT - Displays nodes.
NPRINT - Defines which time points stored are to be listed.
NREAD - Reads nodes from a file.
NREFINE - Refines the mesh around specified nodes.
NRLSUM - Specifies the Naval Research Laboratory (NRL) sum mode combination method.
*NRM - Computes the norm of the specified matrix or vector.
NROPT - Specifies the Newton-Raphson options in a static or full transient analysis.
NROTAT - Rotates nodal coordinate systems into the active system.
NRRANG - Specifies the range of nodes to be read from the node file.
NSCALE - Generates a scaled set of nodes from a pattern of nodes.
NSEL - Selects a subset of nodes.
NSLA - Selects those nodes associated with the selected areas.
NSLE - Selects those nodes attached to the selected elements.
NSLK - Selects those nodes associated with the selected keypoints.
NSLL - Selects those nodes associated with the selected lines.
NSLV - Selects those nodes associated with the selected volumes.
NSMOOTH - Smooths selected nodes among selected elements.
NSOL - Specifies nodal data to be stored from the results file.
NSORT - Sorts nodal data.
NSTORE - Defines which time points are to be stored.
NSUBST - Specifies the number of substeps to be taken this load step.
NSVR - Defines the number of variables for user-programmable element options.
NSYM - Generates a reflected set of nodes.
/NUMBER - Specifies whether numbers, colors, or both are used for displays.
NUMCMP - Compresses the numbering of defined items.
NUMEXP - Specifies solutions to be expanded from mode-superposition analyses or substructure analyses.
NUMMRG - Merges coincident or equivalently defined items.
NUMOFF - Adds a number offset to defined items.
NUMSTR - Establishes starting numbers for automatically numbered items.
NUMVAR - Specifies the number of variables allowed in POST26.
Источник: [https://torrent-igruha.org/3551-portal.html]

Using ANSYS (Fluent) on the HPC System

To use the ANSYS software on the HPC, you will need the following:

  • Access to the HPC system (Contact HPC support if you need an account created).
  • If you plan on using running the ANSYS Graphical Software (such as workbench and Fluent) on the HPC system, you will require a graphical interface to the HPC system.  See Graphical Connection to the HPC System for information on how to do this.

Selecting a different version of the ANSYS Software

For those who already have a HPC account and are using a "graphical" connection, you should be able to start ANSYS Workbench by issuing the following commands (inside a terminal session and within the directory you wish to stored your ANSYS files):

On our HPC system, we actually have different versions of the ANSYS software installed.  Please visit the HPC software Engineering applications listings which lists the different versions of the ANSYS software available on our system.

Therefore if you want to use a different versions of the ansys software, you will need to issue the following commands to unload current version of the software and then load the version you want.

example

Using ANSYS Workbench (Interactively)

For those who already have a HPC account and are using a "graphical" connection, you can start an interactive session to run the ANSYS software .

Note, if you are having issues, you can "purge" all of the loaded software, in which will reduce conflicts, etc.  But you should have to issue these commands for normal usage.


  • or

    To start ANSYS Workbench by issuing the following command (inside a terminal session and within the directory you wish to stored your ANSYS files):

    Or

    Use the above command if you want to force software rendering for the ansys software.

    When using ANSYS workbench, you are able to solve computational fluid dynamics (fluent), or finite element analysis (Mechanical) models.  To ensure ANSYS licenses are not wasted, please close the application down when finished.

    Which "Graphical" connection site should I use?

    On the CQUniversity HPC facilities, we provide a number of options when connecting to the HPC system using a graphical user interface.

    Using the "Strudel software - see Graphical Connection to the HPC System for instructions", you have a number of selection options.

    • HPC Login Node - Marie;
    • HPC Login Node - Curie;
    • GPU Interactive Session; or
    • Standard Interactive Session.

    Users are advised to use one of the "Login Node options", if they are developing a model, or processing a quick model.  If users plan on running any processing jobs, they should select the GPU Interactive Session and Standard Interactive Session option.

    The benefit for using the either the "GPU or Standard Interactive Session" option, is that the processing occurs on the HPC Compute nodes, thus not overloading the login nodes.  If you are using either Interactive Session option, ensure you select the "Stop the Desktop" option, when your modelling/processing has been completed.  This will ensure the resources are freed up for other users to use.

    It has been found that selecting the "GPU Interactive Session" preforms significantly better when using complex 3D models (especially in generating and displaying the model).

    Running ANSYS fluent application across multiple CPU cores

    There is a bug in which if you try to run there ANSYS fluent application across multiple CPU cores on the HPC system within apply the suggested workaround detailed before, it will causes fluent to slow dramatically down (with some jobs taking being 100 times slower)!

    Therefore the following information provides a guide on how to correctly configure the ANSYS software to utilise multiple CPU's to achieve significant perform improved in solving the simulations!

    • Start strudel and select the 'Standard Interactive Session' site option.
    • Enter in the required resources required, If you want to consume an entire HPC compute node, you can select the example options listed below.

      ansys-strudel-settings
      It should be noted that more CPU's won't guarantee it will be faster and in some cases, the more CPU's you select the slower it goes, due to the inter-process communication overhead.
    • Open terminal and then issue the command (to start ANSYS Workbench in software rendering mode)
    • Open your saved workbench project

    • Double click on setup and select to open the 'launcher setup options'

    • Click on the 'Processing Options' parallel and select you requested CPU's.  It is recommended to save one or two CPU's for the communications between the processes.  Therefore, in the above example where I have asked for 24 CPU's, within the ANSYS setup configurations, select 23 CPU's, as this will make solving a lot more efficient.

    • Now for the most important part, click on the 'Show More Options' option and then select the 'Environment tab (If you don't add this environment setting, the program will perform extremely slow.
    • Click on the "Parallel Settings Tab and select the following options:
      • Interconnects - infiniband
      • MPI Types - intel
      • Run types, you can experiment with this, but you can try either Shared Memory or Distributed Memory option

      • ansys-parallel-setup
    • Once the Parallel Settings environment variables have been selected, click on the OK button to proceed with starting the simulation.

    Using the Standalone ANSYS solver launcher application

    The Ansys software has an application that allows you to submit jobs to be solved through their graphical application "".  To use this application, simply follow these steps,

    1. Start a terminal session and issue the command
    2. You will be presented with the “stand alone ANSYS solver launcher application"

    3. Click on the “Browse button” within the Job Name section and then you can search for your "ANSYS" programs



      You can also select the different types of files to look for

    4. It should then show which program you would like to solve manually.

    5. You can select the “High Performance Computing Setup – to make the job run faster by using my CPU resource to solve the problem.  For example, the image below show the problem being solved across 8 CPU’s.
    6. Once you are ready, click on the Run button to fire off your job to be solved.



      You will see the progress of your program in a XTERM window.

    7. After the time required, your problem will be solved.  You can then use the workbench interface to look at the solved model.

    Solving ANSYS jobs non-interactively

    One of the benefits of using the HPC system is that you can submit 1 to many jobs to the HPC scheduler.  Using the Scheduler, you can request more resources (such as CPU's) which can dramatically improve the processing execution time.

    To solve an ANSYS Jobs on the HPC system, you will need to create an input file. In ANSYS Workbench this can be done by selecting Tools -> Write Input File.

    An example of a ANSYS HPC scheduler script - make sure you change any of the requested resources - such as memory - your problem being solve will require:

    ansys.pbs

    Fluent input files reference a CASE file created using the Fluent GUI.

    fluent.in

    An example ANSYS Fluent HPC scheduler script - make sure you change any of the requested resources - such as memory - your problem being solve will require:

    fluent.pbs

    Trouble shooting

    On some older versions of the ANSYS software, there is a minor bug that can cause the software to crash upon start-up.  During the first time you start up the software the “ANSYS Product Improvement Program” window will pop up.  If you select the “No, I would not like to participate” the software will crash.  Please either click on the cross to close the windows or select the “yes” option.  Once the software has started correctly, you can then go into the Help >> ANSYS Product Improvement Program option and then select the “no” option.  This seems to then work fine.

    Источник: [https://torrent-igruha.org/3551-portal.html]

    Table of Contents

    1. About This Reference
    1.1. Conventions Used in This Reference
    1.1.1, ansys Archives. Product Codes
    1.1.2, ansys Archives. Applicable Products
    1.2, ansys Archives. Terminology
    1.3. Command Characteristics
    1.3.1. Data Input
    1.3.2. Free-Format Input
    1.3.3. Nonrestrictive Data Input
    1.3.4, ansys Archives. Condensed Data Input
    1.3.5. Units
    1.3.6, ansys Archives. Command and Argument Defaults
    1.3.7. File Names
    1.3.8. Star and Slash Commands
    2. Command Groupings
    2.1. SESSION Commands
    2.2. DATABASE Commands
    2.3, ansys Archives. GRAPHICS Commands
    2.4. APDL Commands
    2.5. PREP7 Commands
    2.6. SOLUTION Commands
    2.7, ansys Archives. POST1 Commands
    2.8. POST26 Commands
    2.9. AUX2 Commands
    2.10. AUX3 Commands
    2.11. AUX12 Commands
    2.12. AUX15 Commands
    2.13. Mapping Processor Commands
    2.14. DISPLAY Program Commands
    2.15. REDUCED Order Modeling Commands
    3. Command Dictionary
    I. Connection Commands
    ~CAT5IN - Transfers a .CATPart file into the ANSYS program.
    ~CATIAIN - Transfers a CATIA model into the ANSYS program.
    ~PARAIN - Transfers a Parasolid file into the ANSYS program.
    ~PROEIN - Transfers a Creo Parametric part into the ANSYS program.
    ~SATIN - Transfers a .SAT file into the ANSYS program.
    ~UGIN - Transfers an NX part into the ANSYS program.
    II. A Commands
    A - Defines an area by connecting keypoints.
    AADD - Adds separate areas to create a single area.
    AATT - Associates element attributes with the selected, ansys Archives, unmeshed areas.
    ABEXTRACT - Extracts the alpha-beta damping multipliers for Rayleigh damping.
    *ABBR - Defines an abbreviation.
    ABBRES - Reads abbreviations from a coded file.
    ABBSAV - Writes the current abbreviation set to a coded file.
    ABS - Forms the ansys Archives value of a variable.
    ACCAT - Concatenates multiple areas in preparation for mapped meshing.
    ACCOPTION - Specifies GPU accelerator capability options.
    ACEL - Specifies the linear acceleration of the global Cartesian reference frame for the analysis.
    ACLEAR - Deletes nodes and area elements associated with selected areas.
    ADAMS - Performs solutions and writes flexible body information to a modal neutral file (Jobname.MNF) for use in an ADAMS analysis.
    ADD - Adds (sums) variables.
    ADDAM ansys Archives Specifies the acceleration spectrum computation constants for the analysis of shock resistance of shipboard structures.
    ADELE - Deletes unmeshed areas.
    ADGL - Lists keypoints of an area that lie on a parametric degeneracy.
    ADRAG - Generates areas by dragging a line pattern along a path.
    AEROCOEFF - Computes the aero-damping and stiffness coefficients and writes them to an APDL array.
    AESIZE ansys Archives Specifies the element size to be meshed onto areas.
    AFILLT - Generates a fillet at the intersection of two areas.
    AFLIST - Lists the current data in the database.
    AFSURF - Generates surface elements overlaid on the surface of existing solid elements and assigns the ansys Archives node as the closest fluid element node.
    *AFUN - Specifies units for angular functions in parameter expressions.
    AGEN - Generates additional areas from a pattern of areas.
    AGLUE - Generates new areas by "gluing" areas.
    AINA - Finds the intersection of areas.
    AINP - Finds the pairwise intersection of areas.
    AINV - Finds the intersection of an area with a volume.
    AL - Generates an area bounded by previously defined lines.
    ALIST - Lists the defined areas.
    ALLSEL - Selects all entities with a single command.
    ALPHAD - Defines the mass matrix multiplier for damping.
    AMAP - Generates a 2-D mapped mesh based on specified area corners.
    AMESH - Generates nodes and area elements within areas.
    /AN3D - Specifies 3-D annotation functions
    ANCNTR - Produces an animated sequence of a contoured deformed shape.
    ANCUT - Produces an animated sequence of Q-slices.
    ANCYC - Applies a traveling wave animation to graphics data in a modal cyclic symmetry analysis.
    ANDATA - Displays animated graphics data for nonlinear problems.
    ANDSCL - Produces an animated sequence of a deformed shape.
    ANDYNA ansys Archives Produces an animated sequence of contour values through substeps.
    /ANFILE - Saves or resumes an animation sequence to or from a file.
    ANFLOW - Produces an animated sequence of particle flow in a flowing fluid or a charged particle traveling in an electric or magnetic field.
    /ANGLE - Rotates the display about an axis.
    ANHARM - Produces an animated sequence of time-harmonic results or complex mode shapes.
    ANIM - Displays animated graphics data for linear problems.
    ANISOS - Produces an animated sequence of an isosurface.
    ANMODE - Produces an animated sequence of a mode shape.
    ANMRES - Performs animation of results over multiple results files in an explicit dynamic structural analysis or fluid flow analysis with remeshing.
    /ANNOT - Activates graphics for annotating displays (GUI).
    ANORM - Reorients area normals.
    ANPRES - Produces an animated sequence of the time-harmonic pressure variation of an engine-order excitation in a cyclic harmonic analysis.
    ANSOL - Ansys Archives averaged nodal data to be stored from the results file in the solution coordinate system, ansys Archives.
    ANSTOAQWA - Creates an AQWA-LINE input file from the current Mechanical APDL model.
    ANSTOASAS - Creates an ASAS input file from the current ANSYS model.
    ANTIME - Generates a sequential contour animation over a ansys Archives of time.
    ANTYPE - Specifies the analysis type and restart status.
    /ANUM - Specifies the annotation number, type, and hot spot (GUI).
    AOFFST - Generates an area, offset from a given area.
    AOVLAP - Overlaps areas.
    APLOT - Displays the selected areas.
    APORT - Specifies input data for plane wave and acoustic duct ports.
    APPEND - Reads data from the results file and appends it to the database.
    APTN - Partitions areas.
    ARCLEN - Activates the arc-length method.
    ARCTRM - Controls termination of the solution when the arc-length method is used.
    AREAS - Specifies "Areas" as the subsequent status topic.
    AREFINE - Refines the mesh around specified areas.
    AREMESH - Generates an area in which to create a new mesh for rezoning, ansys Archives.
    AREVERSE - Reverses the ansys Archives of an area, regardless of its connectivity or mesh status.
    AROTAT - Generates cylindrical areas by rotating a line pattern about an axis.
    ARSCALE - Generates a scaled set of areas from a pattern of areas.
    ARSYM - Generates areas from an area pattern by symmetry reflection.
    ASBA - Subtracts areas from areas.
    ASBL - Subtracts lines from areas.
    ASBV - Subtracts volumes from areas.
    ASBW - Subtracts the intersection of the working plane from areas (divides areas).
    ASCRES - Specifies the output type for an acoustic scattering analysis.
    ASEL - Selects a subset of areas.
    ASIFILE - Writes or reads one-way acoustic-structural coupling data.
    *ASK - Prompts ansys Archives user to input a parameter value.
    ASKIN - Generates an area by "skinning" a surface through guiding lines.
    ASLL - Selects those areas containing the selected lines.
    ASLV - Ansys Archives those areas contained in the selected volumes.
    ASOL - Specifies the acoustic solver with scattered ansys Archives formulation.
    /ASSIGN - Reassigns a file name to an ANSYS file identifier.
    ASUB - Generates an area using the shape of an existing area.
    ASUM - Calculates and prints geometry statistics of the selected areas.
    ATAN - Forms the arctangent of a complex variable.
    ATRAN - Transfers a pattern of areas to another coordinate system.
    ATYPE - Specifies "Analysis types" as the subsequent status topic.
    /AUTO - Resets the focus and distance specifications to "automatically calculated."
    AUTOTS - Specifies whether to use automatic time stepping or load stepping.
    /AUX2 - Enters the binary file dumping processor.
    /AUX3 - Enters the results file editing processor.
    /AUX12 - Enters the radiation processor.
    /AUX15 - Enters the IGES file transfer processor.
    AVPRIN - Specifies how principal and vector sums are to be calculated.
    AVRES - Specifies how results data will be averaged when PowerGraphics is enabled.
    AWAVE - Specifies input data for an acoustic incident wave.
    /AXLAB - Labels the X and Y axes on graph displays.
    *AXPY - Performs the matrix operation M2= v*M1 + w*M2.
    III. B Commands
    /BATCH - Sets the program mode to "batch."
    BCSOPTION - Sets memory option for ansys Archives sparse solver.
    BETAD - Defines the stiffness matrix multiplier for damping.
    BF - Defines a nodal body force load.
    BFA - Defines a body force load on an area.
    BFADELE - Deletes body force loads on an area.
    BFALIST - Lists the body ansys Archives loads on an area.
    BFCUM - Specifies that nodal body force loads are to be accumulated.
    BFDELE - Deletes nodal body force loads.
    BFE - Defines an element body force load.
    BFECUM - Specifies whether to ignore subsequent element body force loads.
    BFEDELE - Deletes element body force loads.
    BFELIST - Lists the element body force loads.
    BFESCAL - Scales element body force loads.
    BFINT - Activates the body force interpolation operation.
    BFK - Defines a body force load at a keypoint.
    BFKDELE - Deletes body force loads at a keypoint.
    BFKLIST - Lists the body force loads at keypoints.
    BFL - Defines a body force load on a line.
    BFLDELE - Deletes body force loads on a line.
    BFLIST - Lists the body force loads on nodes.
    BFLLIST - Lists the body force loads on a line.
    BFSCALE - Scales body force loads at nodes.
    BFTRAN - Transfers solid model body force ansys Archives to the finite element model.
    BFUNIF - Assigns a uniform body force load to all nodes.
    BFV - Defines ansys Archives body force load on a volume.
    BFVDELE - Deletes body force loads on a volume.
    BFVLIST - Lists the body force loads on a volume.
    BIOOPT - Specifies "Biot-Savart options" as the subsequent status topic.
    BIOT - Calculates the Biot-Savart source magnetic field intensity.
    BLC4 - Creates a rectangular area or block volume by corner points.
    BLC5 - Creates a rectangular area or block volume by center and corner points.
    BLOCK - Creates a block volume based on working plane coordinates.
    BOOL - Specifies "Booleans" as the subsequent status topic.
    BOPTN - Specifies Boolean operation options.
    BSAX - Specifies the axial strain and axial force relationship for beam sections.
    BSMD - Specifies mass per unit length for a nonlinear general beam section.
    BSM1 - Specifies the bending curvature and moment relationship in plane XZ for beam sections.
    BSM2 - Specifies the bending curvature and moment relationship in plane XY for beam sections.
    BSPLIN - Generates a single line from a spline fit to a series of keypoints.
    BSS1 - Specifies the transverse shear strain and force relationship in plane XZ for beam sections.
    BSS2 - Specifies the transverse shear strain and force relationship in plane XY for beam sections.
    BSTE - Specifies a thermal expansion coefficient for a nonlinear general beam section.
    BSTQ - Specifies the cross section twist and torque relationship for beam sections.
    BTOL - Specifies the Boolean ansys Archives tolerances.
    BUCOPT - Specifies buckling analysis options.
    IV, ansys Archives. C Commands
    C*** - Places a comment in the output.
    CALC - Specifies "Calculation settings" as the subsequent status topic.
    CAMPBELL - Prepares the result file for a subsequent Campbell diagram of a prestressed structure, ansys Archives.
    CBDOF - Activates cut-boundary interpolation (for submodeling).
    CBMD - Specifies preintegrated section mass matrix for composite-beam sections.
    CBMX - Specifies preintegrated cross-section stiffness for composite beam sections.
    CBTE - Specifies a thermal expansion coefficient for a composite beam section.
    CBTMP - Specifies a temperature for composite-beam input.
    CDOPT - Specifies format to be used for archiving geometry.
    CDREAD - Reads a file of solid model and database information into the database.
    CDWRITE - Writes geometry and load database items to a file.
    CE - Defines a constraint equation relating degrees of freedom.
    CECHECK - Check constraint equations and couplings for rigid body motions.
    CECMOD - Modifies the constant term of a constraint equation during solution.
    CECYC - Generates the constraint equations for a cyclic symmetry analysis
    CEDELE - Deletes constraint equations.
    CEINTF - Generates constraint equations at an interface.
    CELIST - Lists the constraint equations.
    CENTER - Defines a node at the center of curvature of 2 or 3 nodes.
    CEQN - Specifies "Constraint equations" as the subsequent status topic.
    CERIG - Defines a rigid region.
    CESGEN - Generates a set of constraint equations from existing sets.
    CFACT - Defines complex scaling factors to be used with operations.
    *CFCLOS - Closes the "command" file.
    *CFOPEN - Opens ansys Archives "command" file.
    *CFWRITE - Writes a Mechanical APDL command (or similar string) to a "command" file.
    /CFORMAT - Controls the graphical display of alphanumeric character strings for parameters, components, ansys Archives, assemblies, and tables.
    CGLOC - Specifies the origin location of the acceleration coordinate system.
    CGOMGA - Specifies the rotational velocity of the global origin.
    CGROW - Defines crack-growth information
    CHECK - Checks current database items for completeness.
    CHKMSH - Checks area and volume entities for previous meshes.
    CINT - Defines parameters associated with fracture parameter calculations
    CIRCLE - Generates circular arc lines.
    CISOL - Stores fracture Kaspersky internet security 2020 patch Archives information in a variable.
    /CLABEL - Specifies contour labeling.
    /CLEAR - Clears the database.
    CLOCAL - Defines a ansys Archives coordinate system relative to the active coordinate system.
    CLOG - Forms the common log of a variable
    /CLOG - Copies the session log file to a named file.
    CLRMSHLN - Clears meshed entities.
    CM - Groups geometry items into ansys Archives component.
    CMACEL - Specifies the translational acceleration of an element component
    /CMAP - Changes an existing or creates a new color mapping table.
    CMATRIX - Performs electrostatic field solutions and calculates the self and mutual capacitances between multiple conductors.
    CMDELE - Deletes a component or assembly definition.
    CMDOMEGA - Specifies the rotational acceleration of an element component about a user-defined rotational axis.
    CMEDIT - Edits an existing assembly.
    CMGRP - Groups components and assemblies into an assembly.
    CMLIST - Lists the contents of a component or assembly.
    CMMOD - Modifies the specification of a component.
    CMOMEGA - Specifies the rotational velocity of an element component about a user-defined rotational axis.
    CMPLOT - Plots the entities contained in a component or assembly.
    CMROTATE - Specifies the rotational velocity of an element component in a brake squeal analysis.
    CMSEL - Selects a subset of components and assemblies.
    CMSFILE - Specifies a list of component mode synthesis (CMS) results files for plotting results on the assembly.
    CMSOPT - Specifies component mode synthesis (CMS) analysis options.
    CMWRITE - Writes node and element components and assemblies to a file.
    CNCHECK - Provides and/or adjusts the initial status of contact pairs.
    CNKMOD - Modifies contact element key options.
    CNTR - Redirects contact pair output quantities to a text file.
    CNVTOL - Sets convergence values for ansys Archives analyses.
    /COLOR - Specifies the color mapping for various items.
    /COM - Places a comment in the output.
    *COMP - Compresses a matrix using a specified algorithm.
    COMBINE - Combines distributed memory parallel (Distributed ANSYS) files.
    COMPRESS - Deletes all specified ansys Archives - Creates a conical volume anywhere on the working plane.
    CONE - Creates a conical volume centered about the working plane origin.
    /CONFIG - Assigns values to ANSYS configuration parameters.
    CONJUG - Forms the complex conjugate of a variable.
    /CONTOUR - Specifies the uniform contour values on stress displays.
    /COPY - Copies a file.
    CORIOLIS - Applies the Coriolis effect to a rotating ansys Archives - Specifies "Node coupling" as the subsequent status topic.
    COVAL - Defines PSD cospectral values.
    CP - Defines (or modifies) a set of coupled degrees of freedom.
    CPCYC - Couples the two side faces of a cyclically symmetric model for loadings that are the same on every segment.
    CPDELE - Deletes coupled degree of freedom sets.
    CPINTF - Defines coupled degrees of freedom at an interface.
    /CPLANE - Specifies the cutting plane for section and capped displays.
    CPLGEN - Generates sets of coupled nodes from an existing set.
    CPLIST - Lists the coupled degree of freedom sets.
    CPMERGE - Merges different couple sets with duplicate degrees of freedom into one couple set.
    CPNGEN - Defines, modifies, ansys Archives, or adds to a set of coupled degrees of freedom.
    CPSGEN - Generates sets of coupled nodes from existing sets.
    CQC - Specifies the complete quadratic mode combination method.
    *CREATE - Opens (creates) a macro file.
    CRPLIM - Specifies the creep criterion for automatic time stepping.
    CS - Defines a local coordinate system by three node locations.
    CSCIR - Locates the singularity for non-Cartesian local coordinate systems.
    CSDELE - Deletes local coordinate systems.
    CSKP - Defines a local coordinate system by three keypoint locations.
    CSLIST - Lists coordinate systems.
    CSWPLA - Defines a local coordinate system at the origin of the working plane.
    CSYS - Activates a previously defined coordinate system.
    /CTYPE - Specifies the type of contour display.
    CURR2D - Calculates current flow ansys Archives a 2-D conductor.
    CUTCONTROL - Controls time-step cutback during a nonlinear solution.
    /CVAL - Specifies nonuniform contour values on stress displays.
    CVAR - Computes covariance between two quantities.
    /CWD - Changes ansys Archives current working directory.
    CYCCALC - Calculates results from a cyclic harmonic mode-superposition analysis using the specifications defined by CYCSPEC.
    /CYCEXPAND - Graphically expands displacements, stresses and strains of a cyclically symmetric model.
    CYCFILES - Specifies the data files where results are to be found for a cyclic symmetry mode-superposition harmonic analysis.
    CYCFREQ - Specifies solution options for a cyclic symmetry mode-superposition harmonic analysis.
    *CYCLE - Bypasses commands within a do-loop.
    CYCLIC - Specifies a cyclic symmetry analysis.
    CYCOPT - Specifies solution options for a cyclic symmetry analysis.
    CYCPHASE - Provides tools for determining minimum and maximum possible result values from frequency couplets produced in a modal cyclic symmetry analysis.
    CYCSPEC - Defines the set of result items for a subsequent CYCCALC command in postprocessing a cyclic harmonic mode-superposition analysis.
    CYL4 - Creates a circular area or cylindrical volume anywhere on the working plane.
    CYL5 - Creates a circular area or cylindrical volume by end ansys Archives - Creates a cylindrical volume centered about the working plane origin.
    CZDEL - Edits or clears cohesive zone sections.
    CZMESH - Create and mesh an interface ansys Archives composed of cohesive zone elements.
    V. D Commands
    D - Defines degree-of-freedom constraints at nodes.
    DA - Defines degree-of-freedom constraints on areas.
    DADELE - Deletes degree-of-freedom ansys Archives on an area.
    DALIST - Lists the DOF constraints on an area.
    DAMORPH - Move nodes in selected areas to conform to structural displacements.
    DATA ansys Archives Reads data records from a file into a variable.
    DATADEF ansys Archives Specifies "Directly defined data status" as the subsequent status topic.
    DCGOMG - Specifies the rotational acceleration of the global origin.
    DCUM - Specifies that DOF constraint values are to be accumulated.
    DCVSWP - Performs a DC voltage sweep on a ROM element.
    DDASPEC - Specifies the shock spectrum computation constants for DDAM analysis.
    DDELE - Deletes degree-of-freedom constraints.
    DDOPTION - Sets domain decomposer option for Distributed ANSYS.
    DEACT - Specifies "Element birth and death" as the ansys Archives status topic.
    DEFINE - Specifies "Data definition ansys Archives as the subsequent status topic.
    *DEL - Deletes a parameter or parameters (GUI).
    DELETE - Specifies sets in the results file to be deleted before postprocessing.
    /DELETE - Deletes a file.
    DELTIM - Specifies the time step sizes to be used for the current load step.
    DEMORPH - Move nodes in selected elements to conform to structural displacements.
    DERIV - Differentiates a variable.
    DESIZE - Controls default element sizes.
    DESOL - Defines or modifies solution results at a node of an element.
    DETAB - Modifies element table results in the database.
    /DEVDISP - Controls graphics device options.
    /DEVICE - Controls graphics device options.
    /DFLAB - Changes degree-of-freedom labels for user custom elements.
    DFLX - Imposes a uniform magnetic flux B on an edge-element electromagnetic model.
    DFSWAVE - Specifies the incident planar waves with random phases for a diffuse sound field.
    DIG - Ansys Archives nodes to a surface.
    DIGIT - Specifies "Node digitizing" as the subsequent status topic.
    *DIM - Defines an array parameter and its dimensions.
    /DIRECTORY - Put the file names in the current directory into a string parameter array.
    DISPLAY - Specifies "Display settings" as the subsequent status topic.
    /DIST - Specifies the viewing distance for magnifications and perspective.
    DJ - Specifies ansys Archives conditions on the components of relative motion of a ansys Archives element.
    DJDELE - Deletes boundary conditions on the components of relative motion of a joint element.
    DJLIST - Lists boundary conditions applied to joint elements.
    DK - Defines DOF constraints at keypoints.
    DKDELE - Deletes DOF constraints at a keypoint.
    DKLIST - Lists the DOF constraints at keypoints.
    DL - Defines DOF constraints on lines.
    DLDELE - Deletes DOF constraints on a line.
    DLIST - Lists DOF constraints.
    DLLIST - Lists DOF constraints on a line.
    *DMAT - Creates a dense matrix.
    DMOVE - Digitizes nodes on surfaces and along intersections.
    DMPEXT - Extracts modal damping coefficients in a specified frequency range.
    DMPOPTION - Specifies distributed memory parallel (Distributed ANSYS) file combination options.
    DMPRAT - Sets a constant modal damping ratio.
    DMPSTR - Sets a constant structural damping coefficient.
    DNSOL - Defines or modifies solution results at a node.
    *DO - Defines the beginning of a do-loop.
    DOF - Adds degrees of freedom to the current DOF set.
    DOFSEL - Selects a DOF label set for reference by other commands.
    DOMEGA - Specifies the rotational acceleration of the structure.
    *DOT - Computes the dot (or inner) product of two ansys Archives - Loops repeatedly through the next *ENDDO command.
    DSCALE - Scales DOF constraint values.
    /DSCALE - Sets the displacement multiplier for displacement displays.
    DSET - Sets the scale and drawing plane orientation for a digitizing tablet.
    DSPOPTION - Sets memory option for the distributed sparse solver.
    DSUM - Specifies the double sum mode combination method.
    DSURF - Defines the surface upon which ansys Archives nodes lie.
    DSYM - Specifies symmetry or antisymmetry degree-of-freedom constraints on nodes.
    DSYS ansys Archives Activates a display coordinate system for geometry listings and plots.
    DTRAN - Transfers solid model DOF constraints to the finite element model.
    DUMP - Dumps the contents of a binary file.
    /DV3D - Sets 3-D device option modes.
    DVAL - Defines values at enforced motion base.
    DVMORPH - Move nodes in selected volumes to conform to structural displacements.
    DYNOPT - Specifies "Dynamic analysis options" as the subsequent status topic.
    VI. E Commands
    E - Defines an element by node connectivity.
    EALIVE - Reactivates an element (for the birth and death capability).
    ECPCHG - Optimizes degree-of-freedom usage in a coupled acoustic model.
    EDADAPT - Activates adaptive meshing in an explicit dynamic analysis.
    EDALE - Assigns mesh smoothing to explicit dynamic elements that use the ALE formulation.
    EDASMP - Creates a part assembly to be used in an explicit dynamic analysis.
    EDBOUND - Defines a boundary plane for sliding or cyclic symmetry.
    EDBX - Creates a box shaped volume to be used in a contact definition for explicit dynamics.
    EDBVIS - Specifies global bulk viscosity coefficients ansys Archives an explicit dynamics analysis.
    EDCADAPT - Specifies adaptive meshing controls for an explicit dynamic analysis.
    EDCGEN - Specifies contact parameters for an explicit dynamics analysis.
    EDCLIST - Lists contact entity specifications in an explicit dynamics analysis.
    EDCMORE - Specifies additional contact parameters for a given contact definition in an explicit dynamic analysis.
    EDCNSTR - Defines various types of constraints for an explicit dynamic analysis.
    EDCONTACT - Specifies contact surface controls for an explicit dynamics analysis.
    EDCPU - Specifies CPU time limit for an explicit dynamics analysis.
    EDCRB - Constrains two rigid bodies to act as one in an explicit dynamics analysis.
    EDCSC - Specifies whether to use subcycling in ansys Archives explicit dynamics ansys Archives - Specifies mass scaling and scale factor of computed time step for an explicit dynamics analysis.
    EDCURVE - Specifies data curves for an explicit dynamic analysis.
    EDDAMP - Defines mass weighted (Alpha) or stiffness weighted (Beta) damping for an explicit dynamics model.
    EDDBL - Selects a numerical precision type of the explicit dynamics analysis.
    EDDC - Deletes or deactivates/reactivates contact surface specifications in an explicit dynamic analysis.
    EDDRELAX - Activates initialization to a prescribed geometry or dynamic relaxation for the explicit analysis.
    EDDUMP - Specifies output frequency for the explicit dynamic restart file (d3dump).
    EDELE ansys Archives Deletes selected elements from the model.
    EDENERGY - Specifies energy dissipation controls for an explicit dynamics analysis.
    EDFPLOT - Allows plotting of explicit dynamics forces and other load symbols.
    EDGCALE - Defines global ALE controls for an explicit dynamic analysis.
    /EDGE - Displays only the common lines (“edges”) of an object.
    EDHGLS - Specifies the hourglass coefficient for an explicit dynamics analysis.
    EDHIST - Specifies time-history output for an explicit dynamic analysis.
    EDHTIME - Specifies the time-history output interval for an explicit dynamics analysis.
    EDINT - Specifies number of integration points for explicit shell and beam output.
    EDIPART - Defines inertia for rigid parts in an explicit dynamics analysis.
    EDIS - Specifies stress ansys Archives in an explicit dynamic full restart analysis.
    EDLCS - Defines a local coordinate system for use in explicit dynamics analysis.
    EDLOAD ansys Archives Specifies loads for an explicit dynamics analysis.
    EDMP - Defines material properties for an explicit dynamics analysis.
    EDNB - Defines a nonreflecting boundary in an explicit dynamic analysis.
    EDNDTSD - Allows smoothing of noisy data for explicit dynamics analyses and provides a graphical representation of the data.
    EDNROT - Applies a rotated coordinate nodal constraint in an explicit dynamics analysis.
    EDOPT - Specifies the type of output for an explicit dynamics analysis.
    EDOUT - Specifies ansys Archives output (ASCII format) for an explicit dynamics analysis.
    EDPART - Configures parts for an explicit dynamics analysis.
    EDPC - Selects and plots explicit dynamic contact entities.
    EDPL - Plots a time dependent load curve in an explicit dynamic analysis.
    EDPVEL - Applies initial velocities to parts or part assemblies in an explicit dynamic analysis.
    EDRC - Specifies rigid/deformable switch controls in an explicit dynamic analysis.
    EDRD - Switches a part from deformable to rigid or from rigid to deformable in an explicit dynamic analysis.
    EDREAD - Reads explicit dynamics output into variables for time-history postprocessing.
    EDRI - Defines inertia properties for a new rigid body that is created when a deformable part is switched to rigid in an explicit dynamic analysis.
    EDRST - Specifies the output interval for an explicit dynamic analysis.
    EDRUN - Specify LS-DYNA serial or parallel processing.
    EDSHELL - Specifies shell computation controls for an explicit dynamics analysis.
    EDSOLV - Specifies "explicit dynamics solution" as the subsequent status topic.
    EDSP - Specifies small penetration checking for contact entities in an explicit dynamic analysis.
    EDSTART - Specifies status (new or restart) of an explicit dynamics analysis.
    EDTERM - Specifies termination criteria for an explicit dynamic analysis.
    EDTP - Plots explicit elements based on their time step size.
    EDVEL - Applies initial velocities to nodes or node components in an explicit dynamic analysis.
    EDWELD - Defines a massless spotweld or generalized weld for use in an explicit dynamic analysis.
    EDWRITE - Writes explicit dynamics input to an LS-DYNA input file.
    EEXTRUDE - Extrudes 2-D plane elements into 3-D solids during a 2-D to 3-D analysis.
    /EFACET - Specifies the number of facets per element edge for PowerGraphics displays.
    EGEN - Generates elements from an existing pattern.
    *EIGEN - Performs a modal solution with unsymmetric or damping matrices.
    EINFIN - Generates structural infinite elements from selected nodes.
    EINTF - Defines two-node elements between coincident or offset nodes.
    EKILL - Deactivates an element (for the birth and death capability).
    ELBOW - Specifies degrees of freedom to be coupled for end release ansys Archives applies section constraints to elbow elements.
    ELEM - Specifies ansys Archives as the subsequent status topic.
    ELIST - Lists the elements ansys Archives their attributes.
    *ELSE - Separates the final if-then-else block.
    *ELSEIF - Separates an intermediate if-then-else block.
    EMAGERR - Calculates the relative error in an electrostatic or electromagnetic field analysis.
    EMATWRITE - Forces the writing of all ansys Archives element matrices to File.EMAT.
    EMF ansys Archives Calculates the electromotive force (emf), or voltage drop along a predefined path.
    EMFT - Summarizes electromagnetic forces and torques.
    EMID - Adds or removes midside nodes.
    EMIS - Specifies emissivity as a material property for the Radiation Matrix method.
    EMODIF - Modifies a previously defined element.
    EMORE - Adds more nodes to the just-defined element.
    EMSYM - Specifies circular symmetry for electromagnetic sources.
    EMTGEN - Generates a set of TRANS126 elements.
    EMUNIT - Specifies the system of units for magnetic field problems.
    EN - Defines an element by its number and node connectivity.
    *END - Closes a macro file.
    *ENDDO - Ends a do-loop and starts the looping action.
    *ENDIF - Ends an if-then-else.
    ENDRELEASE - Specifies degrees of freedom to be decoupled for end release.
    ENERSOL - Specifies the total energies to be stored.
    ENGEN - Generates elements from an existing pattern.
    ENORM - Reorients shell element normals or line element node connectivity.
    ENSYM - Generates elements by symmetry reflection.
    /EOF - Exits the file being read.
    EORIENT - Reorients solid element normals.
    EPLOT - Produces an element display.
    EQSLV - Specifies the type of equation solver.
    ERASE - Explicitly erases the current display.
    /ERASE - Specifies that the screen is to be erased before each display.
    EREAD - Reads elements from a file.
    EREFINE - Refines the mesh around specified elements.
    EREINF - Generates reinforcing elements from selected existing (base) elements.
    ERESX - Specifies extrapolation of integration point results.
    ERNORM - Controls error estimation calculations.
    ERRANG - Specifies the element range to ansys Archives read from a file.
    ESCHECK - Perform element shape checking for a selected element set.
    ESEL - Selects a subset of elements.
    /ESHAPE - Displays elements with shapes determined from the real constants, ansys Archives, section definition, or other inputs.
    ESIZE - Specifies the default number of line divisions.
    ESLA - Selects those elements associated with the selected areas.
    ESLL - Selects those elements associated with the selected lines.
    ESLN - Selects those elements attached to the selected nodes.
    ESLV - Selects elements associated with the selected volumes.
    ESOL - Specifies element data to be stored from the results file.
    ESORT - Sorts the element table.
    ESSOLV - Performs a ansys Archives electrostatic-structural ansys Archives - Specifies the matrix multiplier for deactivated elements.
    ESURF - Generates elements overlaid on the free faces of selected nodes.
    ESYM - Generates elements from a pattern by a symmetry reflection.
    ESYS - Sets the element coordinate system attribute pointer.
    ET - Defines a local element type from the element library.
    ETABLE - Fills a table of element values ansys Archives further processing.
    ETCHG - Changes element types to their corresponding types.
    ETCONTROL - Control the element technologies used in element formulation (for applicable elements).
    ETDELE - Deletes element types.
    ETLIST - Lists currently defined element types.
    ETYPE - Specifies "Element types" as the subsequent status topic.
    EUSORT - Restores original order of the element table.
    EWRITE - Writes elements to a file.
    EXBOPT - Specifies file output options in a CMS generation pass.
    *EXIT - Exits a do-loop.
    /EXIT - Stops the run and returns control to the system.
    EXOPTION - Specifies the EXPROFILE options for the Mechanical APDL to ANSYS CFX profile file transfer.
    EXP - Forms the exponential of a variable.
    EXPAND - Displays the results of a modal cyclic symmetry analysis.
    /EXPAND - Allows the ansys Archives of a larger graphic display than represented by the actual finite element analysis model.
    EXPASS ansys Archives Specifies an expansion pass of an analysis.
    *EXPORT - Exports a matrix to a file in the specified format.
    EXPROFILE - Exports Mechanical APDL interface data on selected nodes to an ANSYS CFX Profile file.
    EXPSOL - Specifies the solution to be expanded for mode-superposition analyses or substructure analyses.
    EXTOPT - Controls options relating to the generation of volume elements from area elements.
    EXTREM - Lists the extreme values for variables.
    EXUNIT - Specifies the interface data unit labels to be written to the profile file from Mechanical APDL to ANSYS CFX transfer.
    VII. F Commands
    F - Specifies force loads at nodes.
    /FACET - Specifies the facet representation used to form solid model displays.
    FC - Provides failure criteria information and activates a data table to ansys Archives temperature-dependent stress and strain limits.
    FCCHECK - Checks both the strain and stress input criteria for all materials.
    FCDELE - Deletes previously defined failure criterion data for the given material.
    FCLIST - To list what filmora scrn crack key Archives failure criteria is that you have input.
    /FCOMP - Specifies file compression level.
    FCUM - Specifies that force loads are to be accumulated.
    FCTYP - Activates or removes failure-criteria types for postprocessing, ansys Archives.
    FDELE - Deletes force loads on nodes.
    /FDELE - Deletes a binary file after it is used.
    FEBODY - Specifies "Body loads on elements" as the subsequent status topic.
    FECONS - Specifies "Constraints on nodes" as the subsequent status topic.
    FEFOR - Specifies "Forces on nodes" as the subsequent status topic.
    FESURF - Specifies "Surface loads on elements" as the subsequent status topic.
    *FFT - Computes the fast Fourier transformation of a specified matrix or vector.
    FILE - Specifies the data file ansys Archives results are to be found.
    FILEAUX2 - Specifies the binary file to be dumped.
    FILEAUX3 - Specifies the results file to be edited.
    FILEDISP - Specifies the file containing the graphics data.
    FILL - Generates a line of nodes between two existing nodes.
    FILLDATA - Fills a variable by a ramp function.
    /FILNAME - Changes the Jobname for the analysis.
    FINISH - Exits normally from a processor.
    FITEM - Identifies items chosen by a picking operation (GUI).
    FJ - Specify forces or moments on the components of the relative motion of a joint element.
    FJDELE - Deletes forces (or moments) on the components of the relative motion of a joint element.
    FJLIST - Lists forces and moments applied on joint elements.
    FK - Defines force loads at keypoints.
    FKDELE - Deletes force loads at a ansys Archives - Lists the forces at keypoints.
    FLIST - Lists force loads on the nodes.
    FLST - Specifies data required for a picking operation (GUI).
    FLUXV - Calculates the flux passing through a closed contour.
    FLUREAD - Reads one-way Fluent-to-Mechanical APDL coupling data via a .cgns file with one-side fast Fourier transformation complex pressure peak value.
    /FOCUS - Specifies the focus point (center of the window).
    FORCE - Selects the element nodal force type for output.
    FORM - Specifies the format of the file dump.
    /FORMAT - Specifies format controls for tables.
    *FREE - Deletes a matrix or a solver object and frees its memory allocation.
    FREQ - Defines ansys Archives frequency points for the SV vs. FREQ tables.
    FRQSCL - Turns on automatic scaling of the entire mass matrix and frequency range for modal analyses.
    FSCALE - Scales force load values in the database.
    FSSECT - Calculates and stores total linearized stress components.
    FSSPARM - Calculates reflection and transmission properties of a frequency selective surface.
    FSUM - Sums the nodal force and moment contributions of elements.
    FTRAN - Transfers solid model forces to the finite element model.
    FTYPE - Specifies the file type and pressure type for the subsequent import of source points and pressures.
    FVMESH - Generates nodes and tetrahedral volume elements from detached exterior area elements (facets).
    VIII. G Commands
    GAP - Specifies "mode-superposition transient gap conditions" as the subsequent status topic.
    GAPF - Defines the gap force data to be stored in a variable.
    GAUGE - Gauges the problem domain for a magnetic edge-element formulation.
    GCDEF - Defines interface interactions between general contact surfaces.
    GCGEN - Creates contact elements for general contact.
    /GCMD - Controls the type of element or graph display used for the GPLOT command.
    /GCOLUMN - Allows the user to apply a label to a specified curve.
    GENOPT - Specifies "General options" as the subsequent status topic.
    GEOM - Defines the geometry specifications for the radiation matrix calculation.
    GEOMETRY - Specifies "Geometry" as the subsequent status topic.
    *GET - Retrieves a value and stores it as a scalar parameter or part of an array parameter.
    /GFILE - Specifies the pixel resolution on Z-buffered graphics files.
    /GFORMAT - Specifies the format for the graphical display of numbers.
    /GLINE - Specifies the element outline style.
    /GMARKER - Specifies the curve marking style.
    GMATRIX - Performs electric field solutions and calculates the self and mutual conductance between multiple conductors.
    GMFACE - Specifies the facet representation used to form solid models.
    *GO - Causes a specified line on the input file to be read next.
    /GO - Reactivates suppressed printout.
    /GOLIST - Reactivates the ansys Archives data input listing.
    /GOPR - Reactivates suppressed printout.
    GP - Defines a gap condition for transient analyses.
    GPDELE - Deletes gap conditions.
    GPLIST - Lists the gap conditions.
    GPLOT - Controls general plotting.
    /GRAPHICS - Defines the type of graphics display.
    /GRESUME - Sets graphics settings to the settings on a file.
    /GRID - Selects the type of grid on graph displays.
    /GROPT - Sets various line graph display options.
    GRP - Specifies the grouping mode combination method.
    /GRTYP - Selects single or multiple Y-axes graph displays.
    /GSAVE - Saves graphics settings to a file for later use.
    GSBDATA - Specifies the ansys Archives or applies the load at the ending point for generalized plane strain option.
    GSGDATA - Specifies the reference point and defines the geometry in the fiber direction for the generalized plane strain element option.
    GSLIST - When using generalized plane strain, ansys Archives, lists the input data or solutions.
    GSSOL - Specifies which results to store from the results file when using generalized plane strain.
    /GST - Turns Graphical Solution Tracking (GST) on or off.
    GSUM - Calculates and prints geometry items.
    /GTHK - Sets line thicknesses for graph lines.
    /GTYPE - Controls the entities that the GPLOT command displays.
    IX. H Commands
    HARFRQ - Defines the frequency range in a ansys Archives analysis.
    /HBC - Determines how boundary condition symbols are displayed in a display window.
    HBMAT - Writes an assembled global matrix in Harwell-Boeing format.
    /HEADER - Sets page and table heading print controls.
    HELP - Displays help information on ANSYS commands and element types.
    HELPDISP - Displays help information on DISPLAY program commands.
    HEMIOPT - Specifies options for Hemicube view factor calculation.
    HFANG - Defines or displays spatial angles of a spherical radiation surface for sound radiation parameter calculations.
    HFSYM - Indicates the presence of symmetry planes for the computation of acoustic fields in the near and far field domains (beyond the finite element region).
    HPGL - Specifies various HP options.
    HPTCREATE - Defines a hard point.
    HPTDELETE - Deletes selected hardpoints.
    HRCPLX - Computes and stores in the database the time-harmonic solution at a prescribed phase angle.
    HREXP - Specifies the phase angle for the harmonic analysis expansion pass.
    HROPT - Specifies harmonic analysis options.
    HROCEAN - Perform the harmonic ocean wave procedure (HOWP).
    HROUT - Specifies the harmonic analysis output options.
    X. I Commands
    IC - Specifies initial conditions at nodes.
    ICDELE - Deletes initial conditions at nodes.
    ICLIST - Lists the initial conditions.
    /ICLWID - Scales the line width of circuit builder icons.
    ICROTATE - Specifies initial velocity at nodes as a sum of rotation about an axis and translation.
    /ICSCALE - Scales the icon size for elements supported in the circuit builder.
    *IF - Conditionally causes commands to be read.
    IGESIN - Transfers IGES data from a file into ANSYS.
    IGESOUT - Writes solid model data ansys Archives a file in IGES Version 5.1 ansys Archives - Allows graphics data to be captured and saved, ansys Archives.
    IMAGIN - Forms an imaginary variable from a complex variable.
    IMESH - Generates nodes and interface elements along lines ansys Archives areas.
    IMMED - Allows immediate display of a model as it is generated.
    INISTATE - Defines initial state data and parameters.
    *INIT - Initializes a vector or matrix.
    /INPUT - Switches the input file for the commands that follow.
    /INQUIRE - Returns system information to a parameter.
    INRES - Identifies the data to be retrieved from the results file.
    INRTIA - Specifies "Inertial loads" as the subsequent status topic.
    INT1 - Integrates a variable.
    INTSRF - Ansys Archives nodal results on an exterior surface.
    IOPTN - Controls options relating to importing a model.
    IRLF - Specifies that inertia relief calculations are to be performed.
    IRLIST - Prints inertia relief summary table.
    *ITENGINE - Performs a solution using an iterative solver.
    XI. J Commands
    JPEG - Provides JPEG file export for ANSYS displays.
    JSOL - Specifies result items to be stored for the joint element.
    XII, ansys Archives. K Commands
    K - Defines a keypoint.
    KATT - Associates attributes with the selected, unmeshed keypoints.
    KBC - Specifies ramped or stepped loading within a load step.
    KBETW - Creates a keypoint between two existing keypoints.
    KCALC - Calculates stress intensity factors in fracture mechanics analyses.
    KCENTER - Ansys Archives a keypoint at the center of a circular arc ansys Archives by three locations.
    KCLEAR - Deletes nodes and point elements associated with selected keypoints.
    KDELE - Deletes unmeshed keypoints.
    KDIST - Calculates and lists the distance between two keypoints.
    KEEP ansys Archives Stores POST26 definitions and data during active session.
    KESIZE - Specifies the edge lengths ansys Archives the elements nearest a keypoint.
    KEYOPT - Sets element key options.
    KEYPTS - Specifies "Keypoints" as the subsequent status topic.
    KEYW - Sets a keyword used by the GUI for context filtering (GUI).
    KFILL - Generates keypoints between two keypoints.
    KGEN - Generates additional keypoints from a pattern of keypoints.
    KL - Generates a keypoint at a specified location on an existing line.
    KLIST - Lists the defined keypoints or hard points.
    KMESH - Generates nodes and point elements at keypoints.
    KMODIF - Modifies an existing keypoint.
    KMOVE - Ansys Archives and moves a keypoint to an intersection.
    KNODE - Defines a keypoint at an existing node location.
    KPLOT - Displays the selected keypoints.
    KPSCALE - Generates a scaled set of (meshed) keypoints from a pattern of keypoints.
    KREFINE - Refines the mesh around specified keypoints.
    KSCALE - Generates a scaled pattern of keypoints from a given keypoint pattern.
    KSCON - Specifies a keypoint about which an area mesh will be skewed.
    KSEL - Selects a subset of keypoints or hard points.
    KSLL - Selects those keypoints contained in the selected lines.
    KSLN - Selects those keypoints associated with the selected nodes.
    KSUM - Calculates and prints geometry statistics of the selected keypoints.
    KSYMM - Generates a reflected set of keypoints.
    KTRAN - Transfers a pattern of keypoints to another coordinate system.
    KUSE - Specifies whether or not to reuse the factorized matrix.
    KWPAVE - Moves the working plane origin to the average location of keypoints.
    KWPLAN - Defines the working plane using three keypoints.
    XIII. L Commands
    L - Ansys Archives a line between two keypoints.
    L2ANG - Generates a line at an angle with two existing lines.
    L2TAN - Generates a line tangent to two lines.
    LANBOPTION - Specifies Block Lanczos eigensolver options.
    LANG - Generates a straight line at an angle with a line.
    LARC - Defines a circular arc.
    /LARC - Creates annotation arcs (GUI).
    LAREA - Generates the shortest line between two keypoints on an area.
    LARGE - Finds the largest (the envelope) of three variables.
    LATT - Associates element attributes ansys Archives the selected, unmeshed lines.
    LAYER - Specifies the element layer for which data are to be processed.
    LAYERP26 - Specifies the element ansys Archives for which data are to be stored.
    LAYLIST - Lists real constants material properties for layered elements.
    LAYPLOT - Displays the layer stacking sequence for layered elements.
    LCABS - Specifies absolute values for load case operations.
    LCASE - Reads a load case into the ansys Archives - Specifies "Load case settings" as the subsequent status ansys Archives - Concatenates multiple lines into one line for mapped meshing.
    LCDEF - Creates a load case from a set of results on a results file.
    LCFACT - Defines scale factors for load case operations.
    LCFILE - Creates a load case from an existing load case file.
    LCLEAR - Deletes nodes and line elements associated ansys Archives selected lines.
    LCOMB - Combines adjacent lines into one line.
    LCOPER - Performs load case operations.
    LCSEL - Selects a subset of load cases.
    LCSL - Divides intersecting lines at their point(s) of intersection.
    LCSUM - Specifies whether to process non-summable items in load case operations.
    LCWRITE - Creates a load case by writing results to a load case file.
    LCZERO - Zeroes the results portion of the database.
    LDELE - Deletes unmeshed lines.
    LDIV - Divides a single line into two or more lines.
    LDRAG - Generates lines by sweeping a keypoint pattern along path.
    LDREAD - Reads results from the results file and applies them as loads.
    LESIZE - Specifies the divisions and spacing ratio on unmeshed lines.
    LEXTND - Extends a line at one end by using its slope.
    LFILLT - Generates a fillet line between two intersecting lines.
    LFSURF - Generates surface elements overlaid on the edge of existing solid elements and assigns the extra node as the closest fluid element node.
    LGEN - Generates additional lines from a pattern of lines.
    LGLUE - Generates new lines by "gluing" lines.
    LGWRITE - Writes the database command log to a file.
    /LIGHT - Specifies the light direction for the display window.
    LINA - Finds the intersection of a line with an area.
    LINE - Specifies "Lines" as the subsequent status topic.
    /LINE - Creates annotation lines (GUI).
    LINES - Specifies the length of a printed page.
    LINL - Finds the common intersection of lines.
    LINP - Finds the pairwise intersection of lines.
    LINV - Finds the intersection of a line with a volume.
    LIST - Lists out the sets in the results file.
    *LIST - Displays the contents of an external, coded file.
    LLIST - Lists the defined lines.
    LMESH - Generates nodes and line elements along lines.
    LNSRCH - Activates a line search to be used with Newton-Raphson.
    LOCAL - Defines a local coordinate system by a ansys Archives and orientation.
    LOVLAP - Overlaps lines.
    LPLOT - Ansys Archives the selected lines.
    LPTN - Partitions lines.
    LREFINE - Refines the mesh around specified lines.
    LREVERSE - Reverses the normal of a line, ansys Archives, regardless of its connectivity or mesh status.
    LROTAT - Generates circular lines by rotating a keypoint pattern about an axis.
    LSBA - Subtracts areas from lines.
    *LSBAC - Performs the solve (forward/backward substitution) of a factorized linear system.
    LSBL - Subtracts lines from lines.
    LSBV - Subtracts volumes from lines.
    LSBW - Subtracts the intersection of the working plane from lines (divides lines).
    LSCLEAR - Clears loads and load step options from the database.
    LSDELE - Deletes load step files.
    *LSDUMP - Dumps a linear solver engine to ansys Archives binary File.
    LSEL - Selects a subset of lines.
    *LSENGINE - Creates a linear solver engine.
    *LSFACTOR - Performs the numerical factorization of a linear solver system.
    LSLA - Selects those lines contained in ansys Archives selected areas.
    LSLK - Selects those lines containing the selected keypoints.
    LSOPER - Specifies "Load step operations" as the subsequent status topic.
    /LSPEC - Specifies annotation line attributes (GUI).
    LSREAD - Reads load and load step option data into ansys Archives database.
    *LSRESTORE - Restores a linear solver engine from a binary file.
    LSSCALE - Generates a scaled set of lines from a pattern of lines.
    LSSOLVE - Reads and solves multiple load steps.
    LSTR - Defines a straight line irrespective of the active coordinate system.
    LSUM - Calculates and prints geometry statistics of the selected lines.
    LSWRITE - Writes load and load step option data to a file.
    /LSYMBOL - Creates annotation symbols (GUI).
    LSYMM - Generates lines from a line pattern by symmetry reflection.
    LTAN - Generates a line at the end of, and tangent to, an existing line.
    LTRAN - Transfers a pattern of lines to another coordinate system.
    LUMPM - Specifies a lumped mass matrix formulation.
    LVSCALE - Scales the load vector for mode-superposition analyses.
    LWPLAN - Defines the working plane normal to a location on a line.
    XIV, ansys Archives. M Commands
    M - Defines master degrees of freedom for superelement generation analyses.
    MAGOPT - Specifies options for a 3-D magnetostatic field analysis.
    MAGSOLV - Specifies magnetic solution options and initiates the solution.
    /MAIL - Mails file to the specified address.
    MAP - Maps pressures from source points to target surface elements.
    /MAP - Enters the mapping processor.
    MAP2DTO3D - Initiates a 2-D to 3-D analysis and maps variables.
    MAPSOLVE - Maps solved node and element solutions from an original mesh to a new mesh.
    MAPVAR - Defines tensors and vectors in user-defined state variables for rezoning and in 2-D to 3-D analyses.
    MASCALE - Activates scaling of the entire system matrix.
    MASTER - Specifies "Master DOF" as the subsequent status topic.
    MAT - Sets the element material attribute pointer.
    MATER ansys Archives Specifies "Material properties" as the subsequent status topic.
    MCHECK - Checks mesh connectivity.
    MDAMP - Defines the damping ratios as a function of mode.
    MDELE - Deletes master degrees of freedom.
    MDPLOT - Plots frequency-dependent modal damping coefficients calculated by DMPEXT.
    MEMM - Allows the current session to keep allocated memory
    /MENU - Activates the Graphical User Interface (GUI).
    *MERGE - Merges two dense matrices or vectors into one.
    MESHING - Specifies "Meshing" as the subsequent status topic.
    MFANALYSIS - Activates or deactivates an ANSYS Multi-field solver analysis.
    MFBUCKET - Turns a bucket search on or off.
    MFCALC - Specifies a calculation frequency for a field in an ANSYS Multi-field solver analysis.
    MFCI - Sets the control parameters used by the conservative (CPP) ansys Archives scheme.
    MFCLEAR - Deletes ANSYS Ansys Archives solver analysis settings.
    MFCMMAND - Captures field solution options in a command file.
    MFCONV - Sets convergence values for an ANSYS Multi-field solver analysis.
    MFDTIME - Sets time step sizes for an ANSYS Multi-field solver analysis.
    MFELEM - Defines a field by grouping element types.
    MFEM - Add more element types to a previously defined ansys Archives number.
    MFEXTER - Defines external fields for an ANSYS Multi-field solver analysis.
    MFFNAME - Specifies a file name for a field in an ANSYS Multi-field solver analysis.
    MFFR - Setup Multi-Field relaxation factors for field solutions.
    MFIMPORT - Imports a new field into a current ANSYS Multi-field solver analysis.
    MFINTER - Specifies the interface load transfer interpolation option for an ANSYS Multi-field solver analysis.
    MFITER - Sets the number of stagger iterations for an ANSYS Multi-field solver analysis.
    MFLCOMM - Defines a load transfer for code coupling analyses.
    MFLIST - Lists the settings for an ANSYS Multi-field solver analysis.
    MFMAP - Calculates, ansys Archives, saves, resumes, ansys Archives, or deletes mapping data in an ANSYS Multi-field solver analysis.
    MFORDER - Ansys Archives field solution order for an ANSYS Multi-field solver analysis.
    MFOUTPUT - Specifies results file output frequency for an ANSYS Multi-field solver analysis.
    *MFOURI - Calculates the coefficients for, or evaluates, a Fourier series.
    MFPSIMUL - Aiseesoft Blu-ray Player Crack v6 Method: up a field solver group to simultaneously process with code coupling analyses.
    MFRC - Controls file writing for multiframe restarts for the ANSYS Multi-field solver.
    MFRELAX - Sets relaxation values for an ANSYS Multi-field solver analysis.
    MFRSTART - Specifies restart status for an ANSYS Multi-field solver analysis.
    MFSORDER - Sets up the solution sequence of simultaneous field solver groups for code coupling analyses.
    MFSURFACE - Defines a surface load transfer for an ANSYS Multi-field solver analysis.
    MFTIME - Sets end time for an ANSYS Multi-field solver analysis.
    MFTOL - Activates or deactivates normal distance checking for surface mapping in an ANSYS Multi-field solver analysis.
    *MFUN - Copies or transposes an array ansys Archives matrix.
    MFVOLUME - Defines a volume load transfer for an ANSYS Multi-field solver analysis.
    MFWRITE - Writes an ANSYS master input file for MFX multiple code coupling.
    MGEN - Generates additional MDOF ansys Archives a previously defined set.
    MIDTOL - Sets midstep residual criterion values for structural transient analyses.
    /MKDIR - Creates a directory.
    MLIST - Lists the MDOF of freedom.
    MMASS - Specifies the ansys Archives mass response calculation.
    MMF - Calculates the magnetomotive force along a path.
    MODCONT - Specify additional modal analysis options.
    MODDIR - Activates the remote read-only modal files usage.
    MODE - Specifies the harmonic loading term for this load step.
    MODIFY - Changes the listed values of the data in a set.
    MODMSH - Controls the relationship of the solid model and the FE model.
    MODSELOPTION - Specifies the criteria for selecting the modes to be ansys Archives - Specifies modal analysis options.
    MONITOR - Controls contents of three variable fields in nonlinear solution monitor file.
    *MOPER - Performs matrix operations on array parameter matrices.
    MOPT - Specifies meshing options.
    MORPH - Specifies morphing and remeshing controls.
    MOVE - Calculates and moves a node to an intersection.
    MP - Defines a linear material property as a constant or a function of temperature.
    MPAMOD - Modifies temperature-dependent secant coefficients of thermal expansion.
    MPCHG - Changes the material number attribute of an element.
    MPCOPY - Copies linear material model data from one material reference number to another.
    MPDATA - Defines ansys Archives data to be associated with the temperature table.
    MPDELE - Deletes linear material properties.
    MPDRES - Reassembles existing material data with the temperature table.
    /MPLIB - Sets the default material library read and write paths.
    MPLIST - Lists linear material properties.
    MPPLOT - Plots linear material properties as a function of temperature.
    MPREAD - Reads a file containing material properties.
    MPRINT - Specifies that radiation matrices are to be printed.
    MPTEMP - Defines a temperature table for material properties.
    MPTGEN - Adds temperatures to the temperature table by generation.
    MPTRES - Restores ansys Archives temperature table previously defined.
    MPWRITE - Writes linear material properties in the database to a file (if the LIB option is not specified) or writes both linear and nonlinear material properties (if LIB is specified) from the database to a file.
    /MREP - Enables you to reissue the graphics command macro "name" during a replot or zoom operation.
    MRPM - Defines the revolutions per minute (RPM) for a machine rotation.
    MSAVE - Sets ansys Archives solver memory saving option, ansys Archives. This option only applies to the PCG solver (including PCG Lanczos).
    *MSG - Writes an output message via the ANSYS message subroutine.
    MSHAPE - For elements that support multiple shapes, specifies the element shape to be used for meshing.
    MSHCOPY - Simplifies the generation of meshes that have matching node element patterns on two different line groups (in 2-D) or area groups (3-D).
    MSHKEY - Specifies ansys Archives free meshing or mapped meshing should be used to mesh a model.
    MSHMID - Specifies placement of midside nodes.
    MSHPATTERN - Specifies pattern to be used for mapped triangle meshing.
    MSOLVE - Starts multiple solutions for an acoustic analysis.
    /MSTART - Controls the initial GUI components.
    MSTOLE - Adds two extra nodes from FLUID116 elements to SURF151 or SURF152 elements for convection analyses.
    *MULT - Performs the matrix multiplication M3 = M1(T1)*M2(T2).
    *MWRITE - Writes a matrix to a file in a formatted sequence.
    MXPAND - Specifies the number of modes to expand and write for a modal or buckling ansys Archives. N Commands
    N - Defines a node.
    NANG - Rotates ansys Archives nodal coordinate system by direction cosines.
    NAXIS - Generates nodes for general axisymmetric element sections.
    NCNV - Sets the key to terminate an analysis.
    NDELE - Deletes nodes.
    NDIST - Calculates and lists the distance between two nodes.
    NDSURF - Generates surface elements overlaid on the edge of existing elements and assigns the extra node as the closest fluid element node.
    NEQIT - Specifies the maximum number of equilibrium iterations for nonlinear analyses.
    /NERR - Limits the number of warning and error messages displayed.
    NFORCE - Sums the nodal forces and moments of elements attached to nodes.
    NGEN - Generates additional nodes from a pattern of nodes.
    NKPT - Defines a node at an existing keypoint location.
    NLADAPTIVE - Defines the criteria under which the mesh is refined ansys Archives modified during a nonlinear solution.
    NLDIAG - Sets nonlinear diagnostics functionality.
    NLDPOST - Gets element component information from nonlinear diagnostic files.
    NLGEOM - Includes large-deflection effects in a static or full transient analysis.
    NLHIST - Specify result items to track during solution.
    NLIST - Lists nodes.
    NLMESH - Controls remeshing in nonlinear adaptivity.
    NLOG - Forms the natural log of a variable.
    NLOPT - Specifies "Nonlinear analysis options" as the subsequent status topic.
    NMODIF - Modifies an existing node.
    NOCOLOR - Removes color from graphics displays.
    NODES - Specifies "Nodes" as the subsequent status topic.
    /NOERASE - Prevents the screen erase between displays.
    /NOLIST - Suppresses the data input listing.
    NOOFFSET - Prevents the CDREAD command from offsetting specified data items
    /NOPR - Suppresses the expanded interpreted input data listing.
    NORA - Rotates nodal coordinate systems to surface normal
    NORL - Rotates nodal coordinate systems perpendicular to line normal
    /NORMAL - Allows displaying area elements by top or bottom faces.
    NPLOT - Displays nodes.
    NPRINT - Defines ansys Archives time points stored are ansys Archives be listed.
    NREAD - Reads nodes from a file.
    NREFINE - Refines the mesh around specified nodes.
    NRLSUM - Specifies the Naval Research Laboratory (NRL) sum mode combination method.
    *NRM - Computes the norm of the specified matrix or vector.
    NROPT - Specifies the Newton-Raphson options in a static or full transient analysis.
    NROTAT - Rotates nodal coordinate systems into the active system.
    NRRANG - Specifies the range of nodes to be read from the node file.
    NSCALE - Generates a scaled set of nodes from a pattern of nodes.
    NSEL - Selects a subset of nodes.
    NSLA - Selects those nodes associated with the selected areas.
    NSLE - Selects those nodes attached to the selected elements.
    NSLK - Selects those nodes associated with the selected keypoints.
    NSLL - Selects those nodes associated with the selected lines.
    NSLV - Selects those nodes associated with the selected volumes.
    NSMOOTH - Smooths selected nodes among selected ansys Archives - Specifies nodal data to be stored from the results file.
    NSORT - Sorts nodal data.
    NSTORE - Defines which time points are to be stored.
    NSUBST - Specifies the number of substeps to be taken this load step.
    NSVR - Defines the number of variables for user-programmable element options.
    NSYM - Generates a reflected set of nodes.
    /NUMBER - Specifies whether numbers, colors, or both are used for displays.
    NUMCMP - Compresses the numbering of defined items.
    NUMEXP - Specifies ansys Archives to be expanded from mode-superposition analyses or substructure analyses.
    NUMMRG - Merges ansys Archives or equivalently defined items.
    NUMOFF - Adds a number offset to defined items.
    NUMSTR ansys Archives Establishes starting numbers for automatically numbered items.
    NUMVAR - Specifies the number of variables allowed in POST26.
    Источник: [https://torrent-igruha.org/3551-portal.html]

    How do I ansys Archives ANSYS lock files?

    To protect against data ansys Archives, the ANSYS program employs a file-locking mechanism. File locking helps to prevent you or another user from inadvertently opening a new job with the same name and in the same working directory as a currently running job.

    When you open a job (jobname) from a given working directory, ansys Archives, ANSYS creates a corresponding lock file called jobname.lock in that directory, ansys Archives.  The lock file exists for as long as your job is running, ansys Archives.  If you or someone else attempts to open another job of the same name (and in the same directory) as your currently running job, ANSYS detects the existence of the lock file and does not open the new job.  In interactive mode, Ansys Archives displays a dialog indicating that the file is locked, offering the option to override the lock, ansys Archives.  In batch mode, the program exits, leaving the lock file intact.

    To find and remove Ansys lock files, run
    find ~/ -name “*.lock” -exec rm {} \;

    ANSYS creates and checks for lock files by default.  If you prefer to disable the file-lock feature, specify the ANSYS_LOCK=OFF environment variable in your config60.ans file.

    Posted in: Software

    Источник: [https://torrent-igruha.org/3551-portal.html]

    Connect the Digital Thread with Hybrid Digital Twins, ansys Archives, AI-Enabled Simulation, ansys Archives, and Cloud Computing

    Digital convergence is enabling industries to make the most of the data they collect to inform decisions at every stage of the product life cycle, ansys Archives, connect information technology (IT) with operational technology (OT), ansys Archives, and capitalize on new business models. Where does simulation engineering fit in the broader digital convergence ansys Archives

    Pillars of Innovation: Ansys CTO Talks Digital Twins, Vertical Health Care, ansys Archives, and More at IEEE

    Leading its second day of panels at IEEE, Prith Banerjee, ansys Archives, Chief Technology Officer at Ansys, ansys Archives, delivered a keynote presentation that featured Ansys’ long-term strategies to enable simulation-based product innovation across industries.

    Supporting Phased Array Radar Development in Autonomous Vehicles with Ansys HFSS

    Ansys Gets Into Open Source With GitHub

    Simulation Software in Product Development Drives Digital Transformation at Lightspeed

    PTC’s Brian Thompson and Ansys’ Mark Hindsbo delve into the finding of a three-year Ansys-sponsored study quantifying the return on Investment in Simulation-Led Design Exploration and explore the role of simulation software in the product development process to drive and quicken digital transformation. View this white paper to learn more.

    Democratize Simulation with Automation

    With enhanced integration between Ansys optiSLang and Minerva, democratization of simulation automation is just a few clicks away, ansys Archives, enabling experts and nonexperts to reap the benefits of simulation.

    How to Meet the Top 5 Simulation Process and Data Management Challenges

    A typical day in the life of a simulation engineer involves data gathering data, referencing historical data, ansys Archives, pre-processing the models, solving the simulation problem either locally or via high-performance computing (HPC), post-processing the results, generating reports and archiving data. The process and the level of interaction quickly get complex as more tools, physics and multiple teams are involved.

    Fluid Dynamic Simulations Advance Appliance Designs

    Tighter environmental regulations coupled with more sophisticated user experience requirements pushes the designs into territories where subtle physical behavior starts to play a more prominent role.

    Electric Machines: Simulating the Power to Win

    To beat the competition in the electric vehicle market automakers are focused on ensuring EV powertrains are efficient to design, manufacture and operate. As they race forward with EV development, engineers are increasingly using simulation to leverage the potential of holistically optimizing the powertrain with a systems engineering approach.

    Women in Technology: Simulating Sensors to Advance Autonomous Automobiles

    While autonomy represents an incredibly complex engineering challenge spanning ansys Archives functions, perception systems play a foundational role. Automotive autonomy is only possible if the sensors mounted on the car accurately gather information about the surrounding environment and transmit that data to other systems — such as steering and braking — to trigger an appropriate, ansys Archives, safe response.

    Simulate How Permanent Magnets Impact Medical Implants

    Using Ansys Maxwell, ansys Archives, users can define arbitrary magnet assemblies and evaluate magnetic fields ansys Archives 3D space.

    How one Air Race E team Overcame a Critical Design Challenge With Simulation

    Why Medical Device Design Requires Material Information Management

    Like other product design engineers, ansys Archives, medical device engineers need to know the ansys Archives mechanical properties of a material they plan to use to ensure it’s up to the task. But that’s not enough. They also need to know how the body will react to the device and how the device will react to the body.

    Take Your Engineering Simulation Workflow to the Next Level

    Working with the right data is critical to an efficient workflow, but with all the different stakeholders involved in product design and development, ansys Archives, how do you know where the right data is?

    The Fundamentals of FEA Meshing for Structural Analysis

    To conduct a CAE simulation, ansys Archives, there are three important steps to an analysis: pre-processing, solving and post-processing, ansys Archives. This post discusses the FEA pre-processing step, specifically the importance of a good quality mesh.

    How Partnerships Power Simulation

    The old, siloed approach to product design and development is being replaced by streamlined workflows where an array of hardware and software needs to work together to foster innovation, ansys Archives.

    Simulation User Survey Results: Evolving Workflows Affect HPC Usage

    Ansys launched a research survey last year to find out how engineering organizations are using HPC resources for engineering simulation, ansys Archives.

    Ansys and GLOBALFOUNDRIES Team to Accelerate Photonic Integrated Circuit Design

    How to Model and Simulate Complex Electric Motors

    3D electromagnetic problems become more complex in multiphysics simulations such as noise-vibration and harshness (NVH), ansys Archives.

    Earth Day 2021: Simulation Advances Sustainability

    Engineers understand that the individual components they design and simulate are part of larger assemblies, ansys Archives, ansys Archives are part of larger systems, ansys Archives, which are part of an ecosystem.

    Predator Cycling Optimizes the Cycling Experience With Simulation

    Winning the War on COVID with Ansys Fluent

    Renowned researcher Bert Blocken, Ph.D., ansys Archives, was recently recognized by Engineering.com alongside other pioneering minds, such as Elon Musk and Ansys CEO Ajei Gopal, for his groundbreaking academic research activities in computational fluid dynamics, ansys Archives, wall function development and analysis of basic flow phenomena.

    Register for Simulation World 2021 to Engineer What’s Ahead

    Aerodynamics Simulations with Ansys CFX and Fluent in the UberCloud: Part 1

    Aerodynamics Simulations with Ansys CFX and Fluent in the UberCloud: Part 2

    Engineering Simulations using Ansys in the Cloud: Part 2

    On page 40 is the second part of an article presenting a selection of case studies dealing with engineering simulation in the cloud using ANSYS software LS-DYNA, HFSS, and ANSYS Discovery Live; the first part appeared in the previous edition of the EnginSoft magazine and presented case studies based on ANSYS CFX and Fluent.

    Engineering Simulation using Ansys in the Cloud: Part 1

    In ansys Archives article (page 35), ansys Archives, the first in a series, UberCloud presents ansys Archives series of case studies of cloud-based services for engineering-specific applications and use cases that objectively demonstrate the progress of cloud computing in this sector over the past seven years.

    Ansys Discovery Virtual Launch

    When the Pressure Is On: Preventing Well Blowouts

    Green Machine

    ANSYS Simulation: Room Contamination During Respiratory Therapy

    Liberty University Professor of Mechanical Engineering Dr. Wayne Strasser was recently asked by a company focused on the development of respiratory therapy products to aid them in their research on the spread of COVID-19. The team used Ansys simulation solutions to study the exhale of atomized droplets of saliva and mucus during respiratory therapy in a hospital room.

    ANSYS Simulation: Inhalation and Drug Delivery

    By modeling how inhalers deliver medication to the lungs, simulation helps medical device companies improve inhaler design and helps physicians train their patients on how to use the inhalers for greatest effect. Modeling done by Dr. Yu Feng's Computational Biofluidics and Biomechanics Laboratory at Oklahoma State University.

    ANSYS Simulation: Ventilator Design and Manufacturing

    The medical device industry uses simulation to optimize the design of ventilators. Physics-based simulation is the most effective method to accelerate product development and ensure these devices reach those in need as quickly as possible, ansys Archives. Modeling work performed by ARELabs.

    ANSYS Simulation: Vaccine Production

    Once a vaccine has been identified, one of the biggest challenges facing ansys Archives biopharma industry ansys Archives scaling up the production of the vaccine from laboratory to industrial scale. By using simulation in a virtual environment, drug companies can increase their chances of getting the scale-up process right the first time.

    ANSYS Simulation: Disinfection

    Decontaminating rooms and facilities – whether in preparation for patients or in places where the virus has been identified – helps contain the spread of the virus and protect the health of the vulnerable, ansys Archives. Simulations performed by Ansys partner InSilicoTrials Technologies optimizes the decontamination process to ensure clean rooms.

    ANSYS Simulation: Negative Pressure Room

    Negative pressure rooms (NPRs) can help to reduce healthcare staff's exposure to the virus while attending patients, ansys Archives. Simulation demonstrates different room designs of NPRs and enables teams to optimize the room design, inlet vent placement and blower capacity to avoid oral and nasal plumes from recirculating in the room.

    ANSYS Simulation: Fit the Mask Properly

    Wearing a face mask correctly for an extended period can be uncomfortable and cause irritation, however, it is necessary to ensure the effectiveness of the mask.

    ANSYS Simulation: Wear a Mask

    Masks can reduce the risk of contaminating others by up to 6 times. Adjustments can be made to ensure masks are sealed properly to reduce the risk of possible exposure.

    ANSYS Simulation: Leave Additional Space When Exercising

    Standard social distancing guidelines are insufficient when exercising outside. Analysis by Ansys partners Bert Blocken and Fabio Malizia at TUe & KU Leuven has revealed that substantially more space is required to avoid droplets from the runner or cyclist in front of you.

    ANSYS Simulation: Maintaining Social Distancing

    Viral droplets spread quickly throughout the air. The droplets from a cough will spread to the face, neck and clothing of someone one meter away. At two meters, the risk decreases significantly because gravity ansys Archives the carrier droplets to the ground.

    A Revolution in Healthcare with Simulation

    A Revolution in Healthcare from ANSYS

    Watch this video to get an overview of how ANSYS simulation is helping medical device and pharmaceutical companies save lives by using in silico ansys Archives to safely develop innovative devices and treatment methods in virtual human laboratories. Learn how simulation leads to an incredibly high return on investment for these companies, and how regulatory agencies like the FDA are starting to allow simulation data to be used as part of a faster approval process.

    ANSYS Discovery Live Applications and Use Cases

    ANSYS Discovery Live is a groundbreaking approach to design, allowing anyone to incorporate engineering simulation earlier into product development. Watch this video to see simulation results in real time demonstrating the design of stents, ansys Archives, skis, wireless battery charging systems and control board covers for airplanes — a few of the unlimited applications of Discovery Live.

    How nTop Platform was used to design, analyze and print a fuel-cooled oil cooler

    nTop engineers designed, ansys Archives, analyzed and printed a fuel-cooled oil cooler using nTop Platform, ANSYS CFX and a new additive aluminum alloy developed by HRL Laboratories, ansys Archives. This blog takes you from start to finish in the series that began in late 2019.

    Unlock Breakthrough Heat Exchanger Designs with Gyroids

    Engineers can now use additive manufacturing, topology optimization and computational fluid dynamics (CFD) to build, ansys Archives, optimize and evaluate designs that were previously impossible to produce.

    Why ANSYS Bet on Aras PLM Technology, and Why Aras Tends to Become a “Silent Partner”

    “We believe that simulation is crucial to developing tomorrow's next generation products, and that better data and process management of simulations are needed to enable the digital processes of the future that will support these products,” Peter Schroer. "We see ANSYS and the Aras partnership as a potential game changer to connect simulation to technical processes for traceability, access and reuse throughout ansys Archives product lifecycle, ansys Archives. "

    What is Simulation-Led Design

    What ansys Archives Pervasive Engineering Simulation

    Microsoft partner ANSYS extends ability of Azure Digital Twins platform

    “Collaborating with ANSYS to create ansys Archives advanced IoT digital twins framework provides our customers with an unprecedented understanding of their ansys Archives assets’ performance by leveraging physics and simulation-based analytics.” — Sam George, ansys Archives, corporate vice president of Azure IoT, Microsoft

    Rev-Sim Coffee Break Series: Part 19

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    How to Export Cas & Dat Files From Fluent

    Quote:

    Originally Posted by LuckyTranView Post

    Probably because you asked a question about Workbench in the Fluent forum where more users use Fluent exclusively outside of ansys Archives workbench environment.

    There's no reason to think my inquiry was invalid because of using Fluent within WB. Nowhere in the forum, is there a disclaimer stating such and it's preposterous to think of such, ansys Archives. It's an ANSYS tool that has been integrated into WB, ansys Archives, giving every reason to believe it could be used within WB. In my experience thus far, Fluent functions fine within WB. I started my Fluent journey blindly, ansys Archives, not knowing anything but to open WB and insert a Fluent system. And so far, ansys Archives, I've had good luck, ansys Archives. However, I have run into countless people who scorn Fluent's alleged dysfunctionalities ansys Archives operated within WB. Perhaps me coming in blindly was to my benefit, because I have an open mind about how it can be used in various ways, outside of the mainstream.

    Quote:

    Originally Posted by LuckyTranView Post

    Btw the usual format is .cas and .dat (not gnuzipepd), ansys Archives. If you know these things already. If you're at the level that you are writing gnuzipped files, ansys Archives, it's really odd that you don't know how to write a .cas & .dat file.

    This is not so within WB, ansys Archives. WB zips them to *.gz format by default. So it's not as if I willingly zipped them, ansys Archives, demonstrating advanced user understanding of the tool. And in my opinion, ansys Archives, it's probably more sensible to zip them because it helps manage disk spacing.

    Quote:

    Originally Posted by LuckyTranansys Archives alt="View Post">

    Looking back, ansys Archives, I think it's better than you spent the time in Workbench/Fluent to learn it on your own.

    I agree completely, ansys Archives. Experience on one's own is a ansys Archives teacher, ansys Archives. But a little outside help always greases the wheels a little better.

    Quote:

    Originally Posted by LuckyTranView Post

    Also this is not a support/service Forum on Ansys or any software. You should be expressing your discontent on the Ansys customer support website if these are your feelings. Here your mileage will vary as we do not have service guarantees here, only (sometimes) goodwill.

    I was not seeking service, ansys Archives. I was asking a usage question and again, I saw no disclaimers on the forum stating the specificity of approved inquires that are allowed. And my discontent was toward the lack of response I received from the user base here on the forum, ansys Archives, not at the ANSYS tool, ansys Archives. Yes, I noted a clunky export GUI, ansys Archives, but that was not my focus of the statements and I stated that it was easily worked around, ansys Archives, ansys Archives. Goodwill (sometimes)? Why not all the time? I think users here should have more goodwill. This will lead to better vibes in the community, ansys Archives, driving usage, innovation, ansys Archives, research, and enjoyment higher around the tool, Fluent. It's a complicated tool and much of the knowledge can be shared by the more experienced users onto the newer users, thus propagating the life of the tool into the future. Because if all of the experienced users are unwilling to share goodwill and reach out for the benefit of new folks, ansys Archives, eventually the tool itself, that we all want to use and enjoy, will die, ansys Archives.
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    ANSYS Installation Instructions ansys Archives. Before you install ANSYS, please have the VPN installed on your computer, ansys Archives. Connect to the VPN before you download installation files.

    2. Go to https://ist.njit.edu/software-available-download/ and download ANSYS three ISO files:

    3. Mount the three files to open with Windows Explorer.

    4. Go to Disk1 folder and select Setup, right-click it and choose Run as administrator.

    5. Click Install ANSYS Products.       

    6, ansys Archives. Agree to license and click the arrow on the right side to continue.

    7. Click the arrow to continue.

    8, ansys Archives. Under Hostname 1, enter ucslic1.ucs.njit.edu as a license server and click the arrow to continue.

    9. Click the arrow to continue.

    10, ansys Archives. For Unigraphics NX select Perform configuration at a later time and click the arrow to continue.

    11. Click the arrow to continue.

    12, ansys Archives. Click the arrow to ansys Archives and the installation begins.       

    13, ansys Archives. When prompted click  Browse…  and select Disk2 and Disk3.

    14. When the installation is completed, ansys Archives, click the arrow on the right to continue.

    15. Uncheck Launch survey upon exiting, then click Exit.

    16. Click Exit.

    17. Run ANSYS Workbench and Workbench appears as shown below.

    18. Run ANSYS AIM  and AIM appears as shown below.

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    Support

    Our subscribers are able to use our virtual Cloud accounts hosted here in Kingston, Ontario, if they do not have access to certain CAD tools at their home universities, ansys Archives. Figure 1 shows the CMC Microsystems’ Cloud account hardware configuration.

    These accounts have recently been assigned additional master disk space for temporary “scratch” file read/write activity, ansys Archives. Ansys Archives reason for this addition: During simulations, ansys Archives, ANSYS software will create many files as the program solves a set of numerical values at mesh points, ansys Archives, and uses this solution set to calculate its next solution set, continuing ansys Archives the value difference between successive solutions sets is acceptably low.

    These generated files can overwhelm local account memory and mydata persistent file storage, so our IT group has assigned more space to each account ansys Archives a /scratch directory. This is how to set your ANSYS software to use this extra disk.

    Figure 1. CMC Cloud account hardware configuration.

    Setting a “/scratch” directory in ANSYS Electronics Desktop (EDT)

    To point your ANSYS EDT software to your ansys Archives directory, open the Options windows using the menu link Tools -> Options -> General Options… -> Directories, as shown in Figure 2. Select the Override checkbox and enter the name of the scratch directory you have created, using your ansys Archives account identity; for example, if your assigned account name is “v34567”, you would create and use the directory and path “/scratch/v34567”. Close and re-open ANSYS EDT, checking to make sure you are setting your Temp: path correctly.

    Figure 2. Setting a Temporary Files (Scratch) directory for ANSYS EDT simulations.

    Setting a “/scratch” Directory in ANSYS Workbench (Fluent, ansys Archives, Mechanical, Mechanical APDL)

    To point your ANSYS Workbenchch software to your /scratch directory, ansys Archives, open the Options windows using the menu link Tools -> Options -> Project Management, ansys Archives, as shown in Figure 3. Enter the name of the scratch directory you have created, using your virtual account identity; for example, ansys Archives, if your assigned account name is “v34567”, you would create and use the directory and path “/scratch/v34567”, ansys Archives. Close and re-open ANSYS Workbench, checking to make sure you are setting your Default Folder for Temporary Files path correctly. Then open your project and proceed with your simulation work.

    Figure 3, ansys Archives. Setting a Default Folder for Temporary Files in ANSYS Workbench.

    Setting a “/scratch” Directory in the Fluent Stand-alone Program

    Those subscribers that launch the Fluent Ansys Archives tool directly may designate the /scratch directory using the menu path File -> Preferences ansys Archives Meshing Workflow and type in the /scratch directory path.

    Figure 4. Setting the Temporary files folder from within Fluent from File -> Preferences.

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