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#Labview 2013 software
The authors reported excellent analytical characteristics of the developed LabVIEW-based software system to be achieved: the precision of the determination was 0.7% measured by the relative standard deviation for five replicate measurements of morphine standard, and the limit of detection was determined to be as low as M. The detection is based on chemiluminescence reaction with acidic potassium permanganate in the presence of sodium polyphosphate. developed a LabVIEW-based software for the automation of a sequential injection analysis instrument for the determination of morphine.
#Labview 2013 serial
By selecting hardware modules, such as the PCI-DAQ card or serial port method, and the software modules, different kinds of sensors can be used for creating different chemical instruments allowing extremely flexible solutions for automatic measurements in the physical chemistry research. reported a LabVIEW-based chemical virtual instrument (VI) for temperatures and pressures measurement.
#Labview 2013 manual
This method simplifies the experimental operation, avoids complicated procedures of manual data processing and personal error, and improves veracity and repeatability of the experiment results. When applied to determine the reaction rate constant by pX, it achieved live acquiring, real-time displaying, automatic processing of testing data, generating a report of results, and other functions.
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It can calibrate automatically the slope, temperature, and positioning. described a VI system based on LabVIEW 8.0 for ion analyzer which can measure and analyze ion concentrations in solution, comprising a high input impedance voltmeter (widely used in measuring the EM generated by ion selective electrode), a homemade conditioning circuit, data acquisition board, and a computer. Many configurations of LabVIEW-based VI have been reported until now corresponding to their specific chemical application defined by the user needs. The increased application of self-constructed LabVIEW-based chemical virtual instruments (VIs) is due to their flexibility and ability to satisfy all the specific user requirements combined with the simplicity of the construction. A complete SVET scan over the already proved “true” zones could determine the corrosion rate in any of the zones. The resulting map file can be used further by a scanning vibrating electrode technique (SVET) system for rapid (one pass) “true/false” SVET check of the probable zones only passing through the pit’s centers avoiding thus the entire specimen scan. The pits area, traverse length, and density are also determined by the VI using binary large objects (blobs) analysis. The VI LCIA controls synchronously the digital microscope image taking and its analysis, finally resulting in a map file containing the coordinates of the detected probable pits containing zones on the investigated specimen. A virtual instrumentation (VI) system called VI localized corrosion image analyzer (LCIA) based on LabVIEW 2010 was developed allowing rapid automatic and subjective error-free determination of the pits number on large sized corroded specimens.