RU86300U1 - SOFTWARE AND HARDWARE COMPLEX OF CONTROL OF THE STATE OF THE ELECTROCARDIO EQUIPMENT - Google Patents

Abstract

A hardware-software complex for monitoring the state of electrocardiographic equipment, containing a test signal generator, a universal interface, a scanning device, a signal processing unit, a printing device and a personal computer, in which the test signal generator is connected to the input of the universal interface, the output of which is configured to connect to the input controlled electrocardio equipment, the signal processing unit with the first input is connected to the output of the scanning device, the input of the cat It is made with the possibility of connecting to the output of the controlled cardio equipment, and the first output is connected to a printing device, while the signal processing unit and the test signal generator are made in the form of personal computer software, characterized in that, in order to increase accuracy and expand the functionality, it is additionally equipped with an expert system made in the form of personal computer software with a knowledge base containing knowledge about typical defects cardio equipment, the output of which is connected to a printing device, and the input is connected to the second output of the signal processing unit, to the second input of which a test signal generator is connected.

Description

A useful model of the complex belongs to the field of measuring equipment and can be used to carry out the procedure of metrological verification and diagnose malfunctions of cardiac equipment.

There are known complexes designed to control the state of electrocardiographic equipment, allowing metrological verification in accordance with GOST R 50.2.009-2001 (Recommendations for metrology. Electrocardiographs, electrocardioscopes, electrocardiological analyzers. Verification technique). These complexes include a test signal generator connected to the input of the controlled electrocardiographic equipment, and means for determining and comparing the parameters of the output signals of the controlled electrocardiographic equipment with tables of normalized parameters [1]. The verification procedure at well-known complexes is laborious and unproductive, involves the implementation of a large volume of measuring and computational procedures. Known hardware and software systems for monitoring the status of electrocardiological equipment, which carry out verification of electrocardiographic equipment in an automated mode. Automation of the verification procedure is carried out by measuring the linear dimensions of the recognized edges of the image of the test signal, previously digitized using a scanning device, and automatically comparing them with tables of normalized parameters of the output signal of the cardio apparatus [2].

Closest to the utility model in technical essence is a hardware-software complex for monitoring the state of the electrocardiographic equipment, containing a test signal generator, a universal interface, a scanning device, a signal processing unit, a printing device and a personal computer in which the test signal generator is connected to the input of the universal device interface, the output of which is configured to connect to the input of the controlled electrocardio equipment, the signal processing unit the input is connected to the output of the scanning device, the input of which is configured to connect to the output of the controlled electrocardio device, and the output is connected to the printing device, while the signal processing unit and the test signal generator are made in the form of personal computer software [3]. This complex is taken as a prototype.

In the complex adopted for the prototype, the specified test signals are supplied from the test generator through a universal interface to the input of the controlled cardio equipment, the output signal of which (for example, a cardiogram on paper) is fed to the input of a scanning device that digitizes the image and sends it to the input of the signal processing unit. The signal processing unit automatically compares the linear dimensions of the recognized edges of the received image of the test signals with tables of normalized parameters of the output signal and forms a conclusion about the suitability of the controlled electrocardiographic equipment, which is printed using a printing device.

The complex adopted for the prototype verifies the controlled electrocardio equipment and makes a conclusion about its suitability for use. In this case, however, the image parameters of the test signal are not compared with the test signal itself, but with tables of normalized values of this signal. In addition, it is not possible to establish the nature of equipment defects that cannot be detected by built-in self-diagnosis systems.

Thus, the accuracy of verification and the functionality of the well-known and accepted as a prototype software and hardware complex for monitoring the status of electrocardio equipment are limited.

The proposed utility model solves the problem of increasing the accuracy and expanding the functionality of the hardware-software complex for monitoring the state of electrocardio equipment.

EFFECT: possibility of detecting malfunctions (defects) of electrocardiographic equipment inaccessible to self-diagnosis systems built into the apparatus, with developing recommendations on possible ways to eliminate them, as well as improving the accuracy of metrological verification by comparing the image parameters of the test signal with the test signal itself.

This object is achieved by the fact that the known hardware-software complex for monitoring the state of the ectrocardio apparatus containing a test signal generator, a universal interface, a scanning device, a signal processing unit, a printing device and a personal computer in which the test signal generator is connected to the input of a universal interface which is configured to connect to the input of a controlled electrocardiography, the signal processing unit with the first input it is suitable for the output of the scanning device, the input of which is configured to connect to the output of the controlled electrocardio equipment, and the first output is connected to the printing device, while the signal processing unit and the test signal generator are made in the form of personal computer software, according to the utility model, it is additionally equipped with in the form of personal computer software by an expert system with a knowledge base containing knowledge about typical defects of an electrocardiogram ry, whose output is connected to the printing apparatus, and an input connected to the second output of the signal processing unit, to the second input of which is connected a generator of test signals.

The figure shows a structural diagram of the proposed hardware-software complex control electrocardio equipment.

The hardware-software complex contains test signal generator 2, a signal processing unit 3, and an expert system 4, made in the form of personal computer software, 1, a knowledge base that contains knowledge about typical defects in cardiac equipment. The first output of the signal processing unit 3 and the output of the expert system 4 are connected to the printing device 5, the second output of the signal processing unit 3 is connected to the input of the expert system 4. The test signal generator 2 is connected to the second input of the signal processing unit 3 and the input of the universal interface 6, output which is configured to connect to the input of the controlled electrocardio equipment 7. The signal processing unit 3 by the first input is connected to the output of the scanning device 8, the input of which is configured to Connections to the output of controlled electrocardio equipment 7.

The proposed hardware-software complex works as follows. The generator of test signals 2 generates the necessary test signal of complex shape, close to the electrocardiogram of a person, which, with the help of a universal pairing device 6, is input to the controlled electrocardiographic equipment 7. The output signal of the electrocardiographic equipment 7, for example, in the form of a test signal recorded on paper, is digitized using scanning device 8 and is fed to the first input of signal processing unit 3, the second input of which receives a signal from the test signal generator s 2. In the signal processing unit 2, the following is performed: recognition of the image edges of the test signal; placement of special marks at measuring points; measurement of necessary parameters; comparing the results with tables of normalized parameters of the elements of the ECG test signals at the input and output of the cardio equipment according to GOST R 50.2.009-2001 and the output signal parameters of the test signal generator 2. The result of the processing is a report containing the results of measurements, comparisons and conclusions about the suitability of the cardiography equipment, which is printed using a printing device 5.

The data obtained in the signal processing unit 3, namely, the parameters of the recognized image edges of the test signal and the output signal parameters of the test signal generator, are input to the expert system 4, the knowledge base of which contains knowledge about typical defects of electrocardiographic equipment. Based on the data obtained, the expert system searches for possible defects with the formation of recommendations for their elimination. The results are printed using a printing device 5.

Thus, the proposed hardware-software complex, in comparison with the well-known complex adopted for the prototype, by comparing the image parameters of the test signal with the test signal itself, provides improved accuracy of calibration of electrocardiographic equipment, and by identifying malfunctions (defects) of electrocardiographic equipment inaccessible to the built-in devices self-diagnosis systems, with the development of recommendations on possible ways to address them, significantly expands the functionality.

Claims (1)

A hardware-software complex for monitoring the state of electrocardiographic equipment, containing a test signal generator, a universal interface, a scanning device, a signal processing unit, a printing device and a personal computer, in which the test signal generator is connected to the input of the universal interface, the output of which is configured to connect to the input controlled electrocardio equipment, the signal processing unit with the first input is connected to the output of the scanning device, the input of the cat It is made with the possibility of connecting to the output of the controlled cardio equipment, and the first output is connected to a printing device, while the signal processing unit and the test signal generator are made in the form of personal computer software, characterized in that, in order to increase accuracy and expand the functionality, it is additionally equipped with an expert system made in the form of personal computer software with a knowledge base containing knowledge about typical defects cardio equipment, the output of which is connected to a printing device, and the input is connected to the second output of the signal processing unit, to the second input of which a test signal generator is connected.