Microsurvey Cad 2010 Download 3,7/5 2032votes
Our software library provides a free download of MicroSurvey CAD 2014 22.214.171.1247. The most frequent installation filename for the software is: icad.exe.
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This download was scanned by our antivirus and was rated as virus free. The program belongs to Photo & Graphics Tools. MicroSurvey CAD 2014 was developed to work on Windows 7 or Windows 8 and can function on 32-bit systems. The actual developer of the software is MicroSurvey Software Inc.
The latest installer takes up 516.5 MB on disk. The following versions: 14.3 and 14.0 are the most frequently downloaded ones by the program users. MicroSurvey CAD 2014 is a powerful desktop survey and design program that can be used by surveyors, contractors and engineers. The program includes features such as Complete Survey Drafting, COGO, DTM, Traversing, Volumes, Contouring, Point Cloud manipulation and Data Collection. You may want to check out more software, such as MicroSurvey CAD 2013, MicroSurvey CAD 2015 x64 or MicroSurvey embeddedCAD, which might be to MicroSurvey CAD 2014.
Etap_PowerStation_v16.2_download_tutorials_training ETAP is a fully graphical Enterprise package that runs on Microsoft ® Windows ® 2008, 2012, 7, 8, 8.1 and 10 operating systems. ETAP is the most comprehensive analysis tool for the design and testing of power systems available. Using its standard offline simulation modules, ETAP can utilize real-time operating data for advanced monitoring, real-time simulation, optimization, energy management systems, and high-speed intelligent load shedding.
Has been designed and developed by engineers for engineers to handle the diverse discipline of power systems for a broad spectrum of industries in one integrated package with multiple interface views such as AC and DC networks, cable raceways, ground grid, GIS, panels, arc flash, WTG, protective device coordination/selectivity, and AC and DC control system diagrams. ETAP users must be proficient in using basic operations of Windows ® environment. Use of ETAP does not require training.
However, to facilitate the learning process, OTI provides workshops throughout the year in several locations. (Refer to www.etap.com for the up-to-date training schedule.). ETAP allows you to easily create and edit graphical one-line diagrams (OLD), underground cable raceway systems (UGS), three-dimensional cable systems, advanced time-current coordination and selectivity plots, geographic information system schematics (GIS), as well as three-dimensional ground grid systems (GGS). The program has been designed to incorporate to three key concepts: Virtual Reality Operation The program operation emulates real electrical system operation as closely as possible. For example, when you open or close a circuit breaker, place an element out of service, or change the operating status of motors, the deenergized elements and sub-systems are indicated on the one-line diagram in gray. ETAP incorporates innovative concepts for determining protective device coordination directly from the one-line diagram. Strength points: • EASY: Integrated and modular program with a modern and intuitive interface and a high quality graphics.
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Its industry-leading interactive 3D animation allows you to observe order-related operating deflection shapes from running machinery, resonant vibration and mode shapes from real structures, acoustic shapes, and engineering shapes directly from acquired data. In addition to its photo-realistic interactive animated display, ME’scopeVES contains state of the art tools for performing: • FRF-Based Modal Analysis • Operational Modal Analysis • Vibro-Acoustic Analysis • Dynamics Modeling & Simulation • Structural Dynamics Modification • FEA Model Updating An Operating Deflection Shape (ODS) is the simplest way to see how a machine or structure moves during its operation, either at a specific frequency or moment in time. An ODS contains the overall dynamic response of a structure due to forced and resonant vibration. Time-based ODS animation sweeps a cursor through a set of time histories describing motions at multiple points and directions on a test article. You can stop the animation, back it up, and play it forward to observe in slow-motion phenomena that may have taken place very quickly in real time.
With frequency-based ODS animation, you simply move the cursor to a frequency of interest in your data, and the ODS for that frequency is displayed. With this animation, you can observe resonant vibration as well as order-related and other types of forced vibration. Modal analysis is used to characterize resonant vibration in mechanical structures.
Each resonance has a specific “natural” or modal frequency, a modal damping or decay value, and a mode shape. FRF-Based parameter estimation (or curve fitting) is used to estimate the modal parameters of a structure from a set of FRFs. At the heart of the Basic Modal Analysis option is the ME’scope Polynomial method, an easy to use MDOF curve fitter. This curve fitter can be used to simultaneously extract parameters for multiple modes, especially in cases of high modal density. It can also extract local modes where the resonant vibration is confined to a local region of the structure. The Multi-Reference Modal Analysis option contains all of the features of the Basic Modal Analysis option, plus additional methods for curve fitting a multiple reference set of FRFs.
Multi- Reference curve fitting is used to extract closely coupled modes and repeated roots (two or more modes at the same frequency). This option contains a Stability diagram for locating stable pole estimates, and three additional curve fitting methods: Complex Exponential, Z-Polynomial, and the patented AF Polynomial method. The Standard Edition includes improvements including a new Field Data Editor, Fields Wizard, and field conversion tool.
You can use the improved Spot X+Y default merit function, which is now the fastest way to optimize for small spot sizes. Test different tolerances with a new on/off toggle. Customize the location of your design files. The Professional Edition includes all features available in the Standard Edition, plus the Contrast Optimizer, which uses the innovative new Moore-Elliot method. You can also use the new API documentation interface, with over 20 examples for MATLAB, C++, C#, and Python. The Premium Edition includes all features available in the Standard and Professional editions, plus the ability to trace rays from more than 200 field points, so you can design complex freeform systems with high accuracy.
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A typical offshore jacket structure contains hundreds of beams – in such a scenario, this creates unnecessary and costly manual work. Software for hydrostatic, hydrodynamic and structural analysis. Sesam is used in design and analysis of all types of floating structures, including barges, ships and semi-submersibles, TLPs, FPSOs and spar buoys. Radiation/diffraction software combined with FEM (finite element method) • One common concept model for hydrostatic, hydrodynamic, global or local strength analysis • Intact and damaged stability calculations and Code checks • Hydrodynamic motion analysis in frequency domain • Inclusion of mooring and risers in calculation of motion characteristics. This can be done in a simplified way in HydroD.
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• Mirror Substrate – An issue has been resolved regarding how OpticStudio models the back side of a mirror that has a mechanical semi-diameter that is larger than its clear semi-diameter Sequential analyses and calculations • Through Focus FFT MTF – Improvements have been made to the performance of the Through Focus FFT MTF calculation; the calculation time has been reduced by up to a factor of two in some cases. • Convert File Format – An option to enable or disable fitting of input data to a Gaussian beam has been added to the Convert File Format tool, which converts Optiwave F3D files to OpticStudio ZBF files. Fitting the data to a Gaussian beam is enabled by default.
• Beam File Viewer – An option has been added to the Beam File Viewer so users can change the projection that is used to display ZBF data. This option mimics the option in the Physical Optics Propagation (POP) analysis. • Beam File Viewer - The rendering speed has been improved for the Beam File Viewer in sequential mode.
Non-sequential objects and ray tracing • Faceted Surface objects – An issue has been resolved with the Faceted Surface object in non-sequential mode; the X Half Width is now correctly limited when the shape of the surface is toroidal. • Source Diode – Improvements have been made to the Source Diode object in non-sequential mode; a larger range of angles can now be used for the source distribution in a Gaussian model • Boolean objects – The algorithm that is used to create a Boolean object in non-sequential mode has been improved when one of the parent objects is a Biconic Zernike lens. • Object Editor - Improvements have been made to the user interface for the NSC Object Editor to improve readability of text in the Explorer tree. Programming • ZOS-API – The IAS_PathAnalysis interface is now exposed for COM connections (such as COM connections from C++. • Automatic importing of background images in diagrams from mapping service providers • Node-breaker modeling now fully supported in short circuit and OPF calculations • Calculation of thermal impacts and DC resistance conversion factors in GIC calculations • Better initialization for dynamic simulations with improved messaging • Revised composite load model • New governor models support specification of asymmetrical dead-band in speed signal • GE vendor specific wind models are supplied as part of the standard installation. Zemax.OpticStudio.V16.SP2 OpticStudio is the essential software platform for optical engineers, combining an intuitive user interface with complex physics and interactive visuals to drive faster innovation while reducing development costs. Enabling optical engineers, researchers and scientists to design for manufacturability is the core of our mission.
Zemax puts quick, accurate design tools into the hands of optical engineers with OpticStudio™. Each tool set is aligned with key steps in the engineering design process forming the primary functions of the software. The Analysis, Optimization and Tolerancing tool sets contain an impressive array of physics-based algorithims to analyze, simulate, and optimize optical systems all within tolerance specifications. Analysis Tools - bring ideas to life with a single, seamless software platform that includes the industry’s most comprehensive set of analysis and simulation tools to create/improve optical, illumination, and laser systems. Optimization Tools - automatically improve the performance of optical/illumination designs based on user defined constraints, saving Tolerancing Tools - advanced tools and features that help design engineers incorporate manufacturing and assembly limits into design constraints to ensure manufacturability and production efficiency. To enhance the usability OpticStudio includes a comprehensive set of support modules within the software, including stock lens and materials catalogs, user help files, links to knowledgebase articles, and more. To ensure maximum productivity OpticStudio includes each of these modules at no additional cost.
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EMTPWorks provides many customization and scripting options and one can easily adapt it to match its unique needs. A powerful and super-fast computational engine that provides significantly improved solution methods for nonlinear models, control systems, and user-defined models.
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Parallel + Remote Distributed Processing. Introducing another new paradigm for ray tracing speed and efficiency, ASAP NextGen with CoreMax technology will automatically run parallel processes on all cores on a local PC as well as all cores on up to (5) Remote licenses of ASAP installed on the LAN. In addition, users can control the number of cores accessed on each machine. This combination of parallel and remote distributed processing is another industry first and will make ASAP NextGen the fastest ray tracer with the highest level of computing power of any commercial optical design software. Workflow Manager Provides quick and easy access to command menus for those users less comfortable with but who still need scripting in ASAP NextGen.
Commands can be found in the Search box or in the Workflow Manager tree which has been organized around the standard 4-step simulation process in ASAPgeometry, sources, ray tracing and analysis. Menus are clearly labeled to show the exact information needed to construct the command and ASAP Help is built in to the Workflow Manager dialog. Completed commands are then automatically inserted at the cursor location of the active script.
Alternate Scripting Languages Newly added support for C# and Iron Python as alternate scripting languages with built-in code parsing and debugging. Enhanced support for Visual Basic. Provides extensible code base for these languages. Major Improvements to Existing Features Script Editor New extensible Script Editor with an improved user interface and more control over script syntax, appearance, and keyboard shortcuts.
Provides one-click access to new Optimization and Macro Managers and $SCR Editor. Optimization New optimization interface integrated directly into the Script Editor. Automatically parses INR script to find defined variables for use as Design Variables, Constraints, or Merit Functions. Optimization conditions and visual output at run-time are visible within the INR script window. Macro Manager New feature that automatically parses ASAP Scripts to find macro code which is presented as a list. One-click access to the list allows direct editing of each macro and changes are automatically updated to the Script Editor. $SCR Editor New $SCR Editor acts as a simple two-way forms editor with one-click access to text, integer, and floating point input.
Editor automatically generates corresponding ASAP script and updates to script are automatically seen in the $SCR form. OptiSystem 14 includes several enhancements including a new C++ co-simulation component, updates to our multimode component portfolio (to better support the analysis of spatial mode multiplexed systems), the addition of star and circular QAM constellations for coherent transmission systems, and improvements to our transmitter and receiver component portfolios. Key New Features Introduction of a new Cpp component and Cpp CoSimulation Visualizer to allow users to import or build their own customized C++ algorithms/components and directly co-simulate their customized models (using dynamic link libraries) with any other OptiSystem component. Universal DSP, Decision, QAM Sequence Generator and QAM Sequence Decoder components have been updated to support a broader range of modulation formats, including star and circular QAM constellation formats as well as 32-QAM, 128-QAM, and 256-QAM constellations. Enhancements have been made to the Multimode components library including the introduction of a new Spatial Demultiplexer component, improvements to the Erbium Doped MM Fiber, Ytterbium Doped MM Fiber, Measured-Index Multimode Fiber and Parabolic-Index Multimode Fiber amplifier and fiber models (for modelling spatial multiplexed systems and concatenated fibers) and the integration of LP mode generators into our Spatial Transmitter components.
Components within the Transmitters and Receivers libraries have been improved including the introduction of a new Spectral Light Source component, improvements to the noise models in the APD and PIN components, the addition of thermal noise models to our Analog to Digital and Digital to Analog components and the addition of user-defined PAM amplitude maps to our PAM Coder and Decoder components. Updates to our Measured Filter, Measured Optical Filter, Lightwave Analyzer, View Signal Visualizer and Power Splitters; and the introduction of a new Diffuse Channel component for the modeling of indoor optical wireless systems. New library components and enhancements Co-simulation capabilities: Cpp, Cpp CoSimulation Visualizer We are pleased to announce the launch of our new Cpp component in OptiSystem 14. Designed for users who wish to import or build their own customized C++ algorithms/components, the Cpp component will allow for the direct co-simulation of customized models (using dynamic link libraries) with any other OptiSystem component. It includes an open signal architecture interface to allow users to input and/or output any of OptiSystem’s signal types and complex waveform data arrays.
In addition to the Cpp component, we have launched a new Visualizer, the Cpp CoSimulation Visualizer. The new Cpp CoSimulation Visualizer’s primary function is to duplicate all the signals that are designed to enter the Cpp component thus allowing for signal files to be loaded into the component design project (without OptiSystem running) when running in debug mode. OrcaFlex OrcaFlex is the world's leading package for the dynamic analysis of offshore marine systems, renowned for its breadth of technical capability and user friendliness. Ad1981b Driver Download Win7 more.
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