SU918976A1 - Method of checking devices for procesing chromotographic data - Google Patents

Description

(54) METHOD FOR TESTING DEVICES FOR PROCESSING CHROMATOGRAPHIC INFORMATION

The invention relates to computing and can be used when debugging and checking the separation nodes of overlapping chromatographic peaks in computer programs for automated processing of chromatographic information. .

There is a method of metrological certification of chromatographic information processing facilities, concluded with comparing the areas of chromatographic peaks, fagedite and calculated by a verifiable device and a reference device, realizing a more accurate algorithm for processing chromatographic peaks coming from the generator of peaks, the role of which is played by an analog computer, the formation chromatographic peak in which is implemented by a piecewise approximation by a polynomial of the 2nd degree of the mathematical model of chromat graphic peak P.

However, the application of this method requires the use of an EVMAVM system, where the AVM plays the role of a chromatographic peak simulator, which increases the cost and complexity of the method, and there is no possibility of removing the dependence of the error in calculating the area of the undivided chromatographic peak on the degree of non-separation.

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The purpose of the invention is to improve the accuracy of verification.

The goal is achieved by the fact that in the way of checking devices for processing chromatographic information,

The ts, which includes an imitation generator of chromatographic peaks arriving at the input of a rotating device, and determining their areas, simulates a series of divided peaks, from which the average value of the divided peak is determined, imitations of a series of unseparated peaks with a 39 , and the error of calculations of the device being turned on is judged by the difference in the area of the calodes from the series of unseparated peaks and the average value of the area of the divided peak. trinadilti of chromatographic peaks I-I3, arriving at power metal emoe device. The verification is carried out in the following order. Simulated separated peaks 1-3 with a generator, representing a controlled voltage source, and calculating the average value of the areas calculated by the device, then generating a peak generator, simulating undivided chromatographic peaks 4-13, which are also fed to the inlet device. Due to the constancy of electromechanical conditions of imitation of separated and unseparated chromatographic peaks, the difference in the magnitude of the area of the unseparated peak from the average value of the area of the separated chromatographic peak is the error of the device being turned. At this stage, the results of the proposed method can be used to assess the accuracy of the functioning of the software node for the separation of the overlapping peaks of a rotating device for processing the chromatographic analysis data. For a more in-depth analysis of the operation of the device being turned, the dependence of the calculation error on the area of overlapping chromatographs (} 1 peaks on the degree of their non-separation is removed. For this, the peak generator imitates a series of non-segmented peaks, where the reverse of the descending branch of the peak by the ascending (imitation non-separation) on the calibration scale of the software cam at selected equal intervals of the scale. An imitation of a series of chromatographic peaks, worked out in this way, calculates with a testable device.

the determination of the error in calculating the areas of unseparated peaks depending on the degree of their non-separation is exhausted.

An example of metrological certification of a chromatographic information processing device.

They are used to calculate the errors that occur when a device is divided by a turntable, for all ste. non-separation charges of overlapping chromatographic peaks.

The advantage of the proposed method of calibration of devices for processing chromatographic information in a peak generator is a series of overlapping peaks with different degrees of non-separation with a time quantization step of 1.5 s. A series of chromytographic peaks is drawn on the chart tape of the signal recorder, where from the 1st to the 3rd, the separated peaks are simulated, the areas of which are calculated by a testable device and equal 566, 559, 561 respectively (coded values). Based on the calculated values, the average value of the area of the divided peak is 562 (base value). Then, the peak generator is simulated by a series of undivided peaks from the 4th to the 13th, with varying degrees of non-separation. The areas of simulated unseparated peaks 4–13, which are programmatically separated and calculated by a measurable device, are respectively: .4th peak 559; 6th peak 554-, 8th peak 553; 10th peak 548; 12th peak of 543-, 5th peak of 569-, 7th peak of 570 9th peak of 572-, 11th peak of 576i 13th peak of 580. The differences between the calculated peak areas and the average value of the area of the divided peak will be : 4th peak 562-559-7; 6th peak 562-554 8; 8th peak 562-553 9; 5th peak 569-562 7; 7th peak 570-562 8; 9th peak 572-562 10; 10th Peak 562-548 14th, 12th Peak 562-543 19; 11th peak 576-562 14th, 3rd peak 580-562 18. From. These data show that with an increase in the degree of non-separation of the peaks, the difference between the areas of the unallocated peaks calculated by the verifiable device and the average value of the area of the divided peak increases. The error of the turn-over separation node of the overlapping peaks is about 1% when the peak is not divided at the point close to the base of the peak, and about 3% when the peak is not divided at the point near the peak top. If necessary, a more in-depth analysis of the characteristics of the device being tested is the value of the calculated imoch dz and their differences with the base value

Claims (1)

Claim A method for verifying devices for processing chromatographic information, including simulating a generator of chromatographic peaks received at the input of a device under verification, and determining their areas, characterized in that, in order to increase the accuracy of verification, they simulate a series of divided peaks, from which the average value of the area of the divided pi5 is determined ka, they imitate a series of undivided peaks with an increasing degree of non-separation, and the error of the device being verified is judged by the difference in the area of each series of 10 no separated peaks and the mean peak area divided.