Tsiv measurement software

FontTools is a library for manipulating fonts, written in Python. It’s an indispensable tool for font developers and font tool developers who need to deal with the finer details of TrueType and OpenType fonts, or anyone needing to create or process fonts beyond font editor capabilities.The project includes the TTX tool, that can convert TrueType and OpenType fonts to and from an XML text format, which is also called TTX. It supports TrueType, OpenType, AFM and to an extent Type 1 and some Mac-specific formats.The software is released under an open source license.Features include:TTX — From OpenType To XML And Back. This tool lets users convert binary font files (.otf, .ttf, etc) to the TTX XML format, edit them, and convert them back to binary format:If an input file is a TrueType or OpenType font file, it will be decompiled to a TTX file (an XML-based text format).If an input file is a TTX file, it will be compiled to whatever format the data is in, a TrueType or OpenType/CFF font file.Option to allow virtual glyphs ID’s on compile or decompile.Split tables – save the TTX data into separate TTX files per table and write one small TTX file that contains references to the individual table dumps. This file can be used as input to ttx, as long as the table files are in the same directory.Split glyf table: Save the glyf data into separate TTX files per glyph and write a small TTX for the glyf table which contains references to the individual TTGlyph elements.Specify the folder where the output files are created.Specify which tables to dump or which tables to exclude.Merge partial .ttx files with existing .ttf or .otf files.List brief table info instead of dumping to .ttx.Split tables to separate .ttx files.Disable TrueType instruction disassembly.Supports the following tables: BASE, CBDT, CBLC, CFF, CFF2, COLR, CPAL, DSIG, EBDT, EBLC, FFTM, Feat, GDEF, GMAP, GPKG, GPOS, GSUB, Glat, Gloc, HVAR, JSTF, LTSH, MATH, META, MVAR, OS/2, SING, STAT, SVG, Silf, Sill, TSI0, TSI1, TSI2, TSI3, TSI5, TSIB, TSID, TSIJ, TSIP, TSIS, TSIV, TTFA, VDMX, VORG, VVAR, ankr, avar, bsln, cidg, cmap, cvar, cvt, feat, fpgm, fvar, gasp, gcid, glyf, gvar, hdmx, head, hhea, hmtx, kern, lcar, loca, ltag, maxp, meta, mort, morx, name, opbd, post, prep, prop, sbix, trak, vhea, and vmtx.Other tools:pyftinspect – inspect fonts.pyftmerge – merge fonts.pyftsubset – subset fonts.FontTools requires Python 2.7, 3.4 or later.Website: github.com/fonttools/fonttoolsSupport: ForumDeveloper: Many contributorsLicense: MIT LicensefontTools is written in Python. Learn Python with our recommended free books and free tutorials.Return to Font Tools | Return to Font Editors Popular series The largest compilation of the best free and open source software in the universe. Each article is supplied with a legendary

(I++ DME) specification to operate multiple brands of CMM hardware. The Dimensional Measuring Interface Standard (DMIS) was introduced and allowed offline CMM programming software to build programs for multiple brands of software and hardware, as well as a certain level of data exchange between brands. Software development companies launched hardware-neutral 3D measurement software that could operate multiple brands of scanning arms and laser trackers. This breakthrough was made possible by manufacturers of portable metrology equipment who decided to offer open software development toolkits to interface with their hardware.Hardware-neutral 3D measurement software represented considerable progress, allowing operators to connect to multiple brands of hardware from a single software. However, measurement technologies continued to remain within silos: The CMM and portable metrology measurement workflows were so different that they kept operators working in separate environments. Digital gauges could only be operated from specialized gauging software. Robot-based automated measurement cells were launched using dedicated software solutions that tightly integrated trajectory programming with measurement sequences, creating a new software silo.With these incompatible systems, the only way to combine measurements from multiple software was to aggregate the results externally. A disruptive technological shift was needed to eliminate silos, streamline workflows, and maximize the performance of 3D measurement processes for manufacturers. 2nd evolution:The universal 3D metrology software platform In 2016, InnovMetric broke the mold by launching the first version of PolyWorks|Inspector™ capable of operating portable metrology equipment and CMMs within the same user interface.What made PolyWorks|Inspector 2016 so unique was that it allowed portable metrology and CMM operators to: Use the same workflow and software tools to prepare their inspection projects, execute the measurement sequence, and analyze and report measurement results; and Quickly adapt a measurement sequence to different technologies. For example, operators could adapt an existing CMM inspection project for a portable metrology device within minutes.With these new capabilities, there was no longer a need to duplicate inspection projects, saving considerable time and reducing errors. Measurement operators only had to set up their inspection project, define the measurement sequences, and create the inspection reports once.Since then, InnovMetric has continued to enhance its PolyWorks|Inspector solution. Now, users can: Integrate digital gauges and visual checks into its measurement capabilities, eliminating the digital gauge silo; Preconfigure measurement templates for multiple 3D measurement devices, such as one for a CMM and another for a scanning arm within a single inspection project. Users can choose the template they need according

Unify your 3D Metrology Operations with a Universal Software Platform 3D Dimensional Analysis & Quality ControlUnify Your 3D Metrology Operations With a Universal Software Platform3D Dimensional Analysis & Quality ControlUnify Your 3D Metrology Operations With a Universal Software Platform The invention and improvement of 3D measurement technologies over the past six decades have made it possible to manufacture increasingly sophisticated and high-quality products. It started in the 1960s when coordinate measuring machines (CMMs) arrived in the automotive industry along with the first 3D measurement software. In those days, software engineering was in its infancy, with no standard computer or operating system. As a result, these early 3D measurement products were closed systems and every brand of 3D metrology hardware provided its own software. And so began a culture where multiple software products were required in 3D measurement labs.To this day, some companies use more than five different brands of software for 3D measurement. They may use one or two on their CMMs, typically provided by the CMM manufacturers themselves; two or three for portable metrology systems, such as scanning arms, structured-light scanners, and laser trackers; and one or two for their digital gauges. Issues with using multiple 3D measurement software It’s no surprise that the cost of measuring and the risk of error increase with the number of software products used: Training must be provided for operators to master multiple user interfaces and workflows. Maintenance and software updates must be managed for each product. Measurement projects must be duplicated and adapted for each software solution.When relying on multiple software programs, multiple workflows must be mastered, which hinders the performance of 3D measurement teams because: CMM operators tend to operate only CMMs while portable metrology operators typically specialize in one or two types of portable metrology equipment, creating team silos that restrict mobility and limit teamwork efficiency. Operators build superficial knowledge of each software instead of deepening their knowledge of just one, increasing production time. Data management increases in complexity as each software has its own proprietary format, requiring added processing to aggregate the data into formats that engineering and manufacturing teams can digest. 1st evolution:Hardware-neutral 3D measurement software and standards In the 1990s and 2000s, hardware-neutral 3D measurement software and standards emerged that allowed one software to handle multiple brands of 3D measurement hardware. For example: Several CMM software implemented multiple controller protocols and used the neutral Dimensional Measurement Equipment

Toggle Menu --> Please Confirm Confirm your country to access relevant pricing, special offers, events, and contact information. What are you looking for? No product matches found - System Exception Home Products and Services ... Instrument Measurement Software PXI Software PX0109A Quick I/V Measurement Software for PXIe SMU The PX0109A IV Measurement Software helps control the PXI SMU which makes it easy to setup and perform IV measurements without the need to program. HIGHLIGHTS The PX0109A is an essential and powerful software tool to control the PXIe Precision SMU which supports a variety of functions such as a sweep measurement, a sampling measurement, graphical display functions, and the ability to save test results into CSV files, which makes it easy to quickly set up and perform IV measurements and to display the measurement data in tables and graphs without the need to program.M9601A, M9602A, M9603A, M9614A, and M9615A supportedUp to 10 channels supportedCurrent-voltage sweep measurementCurrent-voltage time-domain measurementSoftware DetailsQuick I/V Measurement Software For PXIe Precision SMU Download Extend the Capabilities of Your Product Want help or have questions?