SU644462A1 - Arrangement for ergometry studies - Google Patents

Description

connected to the input of the output unit; the output of the comparison unit is connected to the input of the output unit.

The data output unit has a switch, a switch control node, a matching node, a code converter, a digital print node, a digital display node, a punch control node, a perforator. The switch outputs are connected to the input of the matching node and the input of the code converter. The outputs of the code converter are connected to the input of the perforator through the control unit of the perforator, with the inputs of the digital printing unit and the digital display. The output of the switch control node is connected to the input of the switch.

The physiological parameters extraction unit has the amplification and transformation unit, the primary feature extraction unit, the electrocardiogram measurement unit, the electrocardiogram arrhythmia measurement unit, the interval increment measurement unit, the normalization and scaling unit, the 57-segment displacement signal measurement unit, the node measuring the amplitude of the electrocardiogram Tube, the unit measuring the volume of blood circulation, the unit measuring the volume of respiration. The inputs of the last four nodes are connected to the outputs of the amplification and conversion node, and their outputs are connected to the inputs of the normalization and scaling node, the outputs of the primary feature extraction node are connected to the inputs of the interval measurement nodes, increments of the 7 ../ interval and arrhythmias of electrocardiosigial. The inputs of the electrocardiogram arrhythmia measurement unit are connected to the outputs of the measurement units of the / -interval and the increments of the duration, / -interval of the electrocardiogram. The output of the amplification and conversion node is connected to the input of the primary feature extraction node.

The drawing shows the block diagram of the device for ergometric studies.

The device contains a simulator 1 (e.g. a bicycle ergometer), sensors 2 located on the patient and connected to the inputs of the amplification and conversion unit 3 of the physiological parameters extraction unit 4, which amplifies, measures, normalizes and scales the physiological parameters. The outputs of the amplification and conversion node 3 are connected to the input of the displacement measuring node 5 of the ST segment of the electrocardiogram, the amplitude T-wave of the electrocardiogram amplitude 6, the circulation volume measuring node 7, the breathing volume measuring node 8, and through the node 9 RR-vio.tv of electrocardiogram, node AND measuring arrhythmias of electrocardiogram, node 12 measuring the increments of the length of the / / -interval. The outputs of nodes 5, 6, 7, 8 through node 13 normalization and scaling,

switching unit 14, analog-to-digital converter 15, connected in series, is connected to computing unit 16. Computing unit 16 calculates the expectation of the measured parameters of the ST segment displacement, amplitude of the electrocardiogram T-wave, circulatory volume and respiratory volume. The outputs of the nodes 6, 7, 8 and the computing unit 16 are connected to the inputs of the switch 17 of the block 18 data output. A computer is connected to the output of the switch 17 via a node 19 of the matching, and a digital printing unit 21 and a digital display unit 22 are connected through a code converter 20. The matching unit 19 is connected via a perforator control unit 23 to the perforator 24. The outputs of the arrhythmia measurement unit 11 and the computing unit 20 are connected to the inputs of the comparison unit 25, one of the inputs of which is connected to the control installation unit 26, and the outputs are connected to the display unit 27, with the unit 28 load control and with the unit 29 measuring the work performed. The output of the load control unit 28 is connected to the input of the simulator 1, and one of the outputs of the latter is connected to the input of the unit

29 measuring the work performed, the output of which is connected to the digital printing unit 21. The device has a central unit

30, which is connected to the switching unit 14, the analog-to-digital converter 15, the computing unit 16, the comparison unit 24, the control set unit 26 and the switch 17 via the control node of the switch 31.

The device works as follows.

Claims (3)

The patient is located on the simulator 1. The signals from the sensors 2 located on the patient, are fed to the input of the node 3 for the conversion and amplification of biological signals. The output signals of the node 3 are fed to the inputs of the nodes 5-8 and to the input of the node 9 of the extraction of the primary signs, which produces sync pulses on the .R-teeth of the electrocardiogram. The output signals of node 9 arrive at nodes 10, 11, 12, which, according to time and logical signs, measure the duration of the intervals, the increment of the / interval is determined by the presence of extrasystoles (RjR, ARR). At nodes 5-8, the functional and logical indications of the displacement of the 5G segment of the amplitude of the electrocardiogram, the volume of blood circulation and the volume of respiration are measured. The output signals of these nodes, presented in analog form, are fed to the inputs of the node 13 of normalization and mass stabilization, which ensures their reduction to a single scale of measurements. The output signals from node 13 are alternately connected by the switch unit 14 to the analog-to-digital converter 15. The analog-to-digital converter unit 15 converts the incoming analog signals into a digital binary code. The output signals of this block in the same pattern arrive at the inputs of the computing block 16. In the computing block 16, the expectation of the measured parameters of the displacement of the ST segments, the amplitude of the T-wave electrocardiogram of the circulatory volume and the respiratory volume are measured in a time interval commensurate with the control time constant cardiovascular system, which increases the accuracy of measurement of these parameters in transitional, during stress test, modes. The output signals of the nodes 10-12 and block 16 are fed to the inputs of the switch 17 of the data output unit 18 and the comparison unit 25. In the event that one or several body parameters go beyond the tolerance limits of the settings entered by the control set block 26, signals appear at the output of the comparison block 25, which are fed to the inputs of the load control block 28, which disconnects the load, thereby ensuring the safety of the load test, to the inputs of the unit 29 measuring the work performed, which determines the work performed by the subject, which characterizes quantitatively the reserve of the cardiovascular and respiratory systems, expressed in work units, to the input display unit 27 and unit 18 inputs data output. The organization of work of all units of the device is built on a combined control scheme — the synchronous-asynchronous principle and is carried out by the central control unit 30, whose outputs are connected to the input of blocks 14, 15, 16, 25, 18, 26, thereby increasing the reliability of the device and the organization operation of all units of the device. The output signals from the node 19 approval is fed to the input of the computer. The design of the system provides for the presentation of a standard load strategy to all the examined patients (within the study group), which allows to obtain comparable results when examining different patients or re-examining one patient. The measured parameters are correlated with the amount of work done, which significantly increases the diagnostic information content of the conducted sample. The high degree of automation of the proposed device makes it possible to use it as a highly efficient means for monitoring the dynamics of indicators of the examined persons, for professional selection, for early detection of the pathology of the cardiovascular system., Y ,. Claim 1. An ergometric research device comprising a simulator, sensors, a physiological parameters extraction unit, a data output unit, a comparison unit, a control setpoint unit, a display unit, a load control unit, the sensors being connected to the inputs of the selected unit. physiological parameters, the outputs of which are connected to the data output unit and the inputs of the comparator unit, one of the inputs of the comparator unit is connected to the output of the control setpoint unit, the outputs of the comparator unit are connected to the inputs of the display unit and the load control unit, the output of the latter is connected to the simulator, that, in order to increase the accuracy and objectivity of monitoring the patient’s physiological state by the magnitude of the reserves of his functional systems when carrying out stress tests, it has a switching unit, and tax-digital converter, computing unit, central control unit, measuring unit of work performed, the switching unit inputs connected to the outputs of the physiological parameters extraction unit, and its output through the analog-digital converter connected to the input of the computing unit, the outputs of the latter connected to the inputs of the unit data output and comparison unit, the outputs of the central control unit are connected to the inputs of the switching unit, comparison, data output, control setpoint, to the analogue digital input the converter and the input of the computing unit, the inputs of the measurement unit of the work being performed are connected to the output of the simulator and the output of the comparison unit, and its output is connected to the input of the data output unit, the output of the comparison unit is connected to the input of the data output unit. 2. The device according to claim 1, wherein the data output unit has a switch, a switch control node, a matching node, a code converter, a digital printing node, a digital display node, a punch control node, a perforator, the switch outputs are connected to the input of the matching node the code converter input, the code converter outputs are connected to the punch input through the punch control node, to the digital printing node and the digital display node, the output of the control node by the switch is connected to input switch. 3. The device according to claim 1, characterized in that in it the physiological parameters extracting unit has a gain and conversion unit, a primary feature selection unit, an electrocardiogram measurement unit /, an electrocardiogram arrhythmia measurement unit, an RR-HH interval increment measurement unit , node of normalization and scaling, node for measuring the displacements of the 57-segment electrocardiogram, node for measuring the amplitude of the 7-wave of the electrocardic signal, blood circulation volume measurement node, respiratory volume measurement node, the inputs of the last four nodes are connected to the outputs of the amplification and conversion node, and their outputs are connected to the inputs of the normalization and scaling node, the outputs of the primary feature extraction node are connected to the inputs of the measurement / interval nodes, increments of duration -intervals and arrhythmias of the electrocardiogram, the inputs of the electrocardiogram arrhythmia measurement node are connected to the outputs of the measurement nodes of the J-interval and the increments of the duration of the / 7-interval of the electric diosignala, the output node amplifying and converting an input node coupled to the primary isolation characteristics. Sources of information taken into account in the examination 1. US Patent No. 3845576, cl. 128-2, publ. 1974.