UA14108U - Device for electropuncture diagnosis - Google Patents

Abstract

The device for the electropuncture diagnosis comprises microprocessor, the input limiter-converter, and the measuring electrodes. Furthermore, the device comprises the memory, the controlled commuter of the measuring circuit, the graphic liquid-crystal indicator, the keyboard, and the infrared communication interface connected to the processor. The device also contains the acoustic emitter, the controlled source of the reference voltage for the measuring circuit, the controlled power supply unit, and the unit of the real time.

Description

Description of the invention

The useful model relates to medical diagnostic equipment, namely, to electronic devices for 2 electropuncture diagnostics.

Known device for diagnostics (1) containing active and passive electrodes, reference voltage source, reference resistor, comparator, binary counter, code resistors, first, second and third optocouplers, threshold pressure sensor, diagnostic register, control register, address decoder , register management scheme.

The disadvantage of the device is that measurement errors are allowed due to deviations in the characteristics of the complex, the complexity of the device, and the duration of the diagnostic time.

The closest in terms of technical essence and the result achieved is a device for pulse and electropuncture diagnostics |2), which contains a sensor, an analog amplifier, an analog-to-digital converter, an electronic computing unit, a video terminal, a printer, an indicator, a pulse distributor, 12 non-volatile memory igniting device, comparison unit, n-electronic keys and n-resistors.

Disadvantages of the device are as follows: - Expensive; - Large sizes; - Increasing the time of diagnosis; - Availability of a personal computer in the diagnostic complex; - There is no account of the impact of transient processes in the patient's body on the accuracy of the measurement.

The basis of a useful model is the task of creating a device for electropuncture diagnostics, which is made on analog, digital and microprocessor technology with a high degree of algorithmization and minimization, which provides portability, the possibility of autonomous operation without a personal computer, the possibility of displaying the results of the patient's examination on a graphic indicator , the possibility of memorizing the data obtained for any number of patients in each of the three measurement modes, increasing the reliability of the results in the process of long-term studies due to the use of a measuring chain switch controlled by a special algorithm, which allows you to carry out a mass survey of the population with high reliability as in both in and out of the hospital. co

The task is solved due to the fact that the device for electropuncture diagnostics, which Ha") includes a microprocessor, an input limiter-converter, measuring electrodes, according to a useful model, a memory device connected to the processor is introduced, a controlled switch of the measuring circuit is connected to of the processor, sound emitter, software-controlled by the processor in accordance with the change /"f the measured value, graphic liquid crystal indicator connected to the output of the processor, controlled 3o reference voltage source for measurement circuits, keyboard connected to the processor, infrared - communication interface, connected to the processor, a controlled power supply connected to the circuit elements, and a real-time clock unit.

The drawing shows the structural diagram of the device. "

The device contains a microprocessor 1, an electrically erasable and reprogrammable memory device (ESPPZP) 2, a graphic liquid crystal display (LCD) 3, a keyboard 4, a sound emitter 5, an infrared communication interface (IKI) 6, a controlled power supply unit ( KBZh) 7, managed

From" reference voltage source for measuring circuits (DON) 8, switch of the measuring circuit 9, active electrode 10, passive electrode 11, input limiter-converter 12, real-time clock 13.

Microprocessor 1 is designed to execute a sequence of commands from its internal memory according to the device's operating algorithm, to perform user interface functions by monitoring keystrokes and displaying information on LCD 3. variables necessary for the operation of the device. It is structurally made on the Zegpai EERKOM chip and allows multiple (up to 100,000 times) overwriting. Data in ESPPZP 2 are stored regardless of the availability of power supply! 20 devices for at least 10 years.

The graphic RKI Z is designed to display in graphic and/or symbolic form the results of measurements in all modes of operation of the device and symbols for monitoring the status of the device. The indicator allows you to get a graphic image with a size of 128x64 pixels.

The keyboard 4 consists of several buttons placed on the front panel of the device and one button on the active electrode 25. The keyboard is intended for the user to select the operating mode of the device and enter the information necessary to create a record of the measurement results.

Sound emitter 5 is designed to create an additional acoustic interface with the user in various operating modes of the device and to enhance the tactile effect of working with the keyboard.

The infrared communication interface (IKI) 6 is intended for optical wireless transmission on request of 60 data of measurement records to a personal computer or other device. The maximum possible transmission distance is 2 meters.

The controlled power supply unit 7 is designed to generate the power supply voltage for all components of the device, provide information about the current state of the batteries, and turn off the power supply of the device at the request of the microprocessor 1.

The controlled reference voltage source 8 is designed to generate the 710V voltage required for the measuring circuits of the device. In order to save electricity, this DON is turned on and off, if necessary, by microprocessor 1.

The commutator of the measuring circuit 9 is designed to provide control of the measurement processes by the microprocessor 1.

The active electrode 10 is designed to search for biologically active points (BAT) on the human body, measure at these points and fix the measurement results using the keyboard button 4 placed on it.

The passive electrode 11 is designed to create a closed electrical measurement circuit.

The input limiter-converter 12 is designed to prepare the measurement signal for analog-to-digital conversion by the built-in means of the microprocessor 1. 70 The real-time clock 13 is designed to fix the time and date of the measurement in the record of the measurement results.

The device works like this.

When the power is turned on, the controlled power supply unit 7, in the presence of a charged battery, generates all the necessary voltages for powering the device blocks and generates the initial reset signal of the microprocessor 1.

Microprocessor 1 loads the program for testing and calibrating the device blocks from the internal memory.

Microprocessor 1 performs testing and calibration of the following device blocks: ESPPZP 2, LCD 3, controlled reference voltage source for measuring circuits 8, measuring circuit switch 9, real-time clock 13. After testing, microprocessor 1 displays on the LCD screen the test results of the device blocks and an invitation to start of work Further control of the device is performed by the user using keyboard 4.

From DON 8 reference voltage 4108 is supplied to the commutator of the measuring circuit 9 to supply the measuring voltage to the electrodes in the time segments determined by the algorithm of the device. From the commutator of the measuring circuit 9, the measuring voltage is applied to the active electrode 10. The measured value, which is proportional to the conductivity of the skin of the human body at the point under investigation, is fed through the passive electrode 11 to the input limiter-converter 12. The signal from the output of the limiter-converter is applied to analog-to-digital converter implemented on a microprocessor 1. After the analog-to-digital conversion, the value of the measured value is processed by the microprocessor according to the device's operation algorithm.

If it is necessary to further process the received data on a personal computer, an infrared communication interface 6 is introduced into the device, through which measurement data is transmitted to the personal computer.

For the convenience of the user, an additional sound interface 5 has been introduced into the device, which has the option of software activation and deactivation at the user's request. "-

When the battery is discharged, the device issues a message about this on the LCD.

The device has three main modes of operation: the search mode for biologically active points, the diagnostic mode, and the mode for monitoring the state of biologically active points. Modes are switched from the keyboard. "-

In the search mode, the user detects biologically active points by moving the active electrode over the patient's body (the passive electrode is fixed on the body motionless). Measuring voltage pulses of 10 volts with a current limit of 10 microamps are applied to the patient's body with a frequency of 1 second, the measurement results are processed in the device and displayed on the LCD. Also possible sound "

Control of the measured value (switched on and off from the keyboard). з с In the diagnostic mode, 24 measurements are made at biologically active points, the active electrode is installed

And at point i, a button located on the electrode is pressed, a measurement is made, and the data is recorded. in ESPPZP they are taken to RKI. The device offers to measure at the next point. At the end of the last 24th measurement, the device processes the received data, displays the results in the form of a graph on the LCD. Sound control is also possible in this mode. - The monitoring mode serves to monitor the patient's condition over a certain period of time. Instead of an active electrode, one more passive electrode is connected, and these two electrodes are installed in the necessary biologically active points. Every 3 seconds, a measurement is made and the result is displayed on the RKI with an indication of the percentage deviation from the initial measurement. The regimen is necessary when studying the impact of various therapeutic factors on the patient. o The positive effect of using the device consists in increasing the reliability of the results during the examination due to the speed of measurements, eliminating errors during measurements, as well as ensuring convenience and ease of use, especially in the ability to work without a computer.

Increasing the reliability of measurements is achieved as follows. After applying the measuring voltage to the patient's brain, transient electrical processes occur in it, caused by the resistance and capacitance of the body, which continue for 20-40 milliseconds. At this time, significant fluctuations of the current passing through the body are observed. In the device, the measurement of values begins 50 milliseconds after the measurement voltage is applied, when the transient processes have already ended and the current value is set to constant. In addition, 5 measurements are taken with an interval of 10 milliseconds for the next 50 milliseconds, and their average value is calculated. In order to increase the reliability of measurements, a 3-minute limit has also been introduced for all 24 measurements carried out in the diagnostic mode. This is caused by the fact that the conductivity of the human body depends to a large extent on the emotional and physical state at this particular moment in time. And the faster the entire set of measurements is made, the more objective a picture can be obtained. If all 24 measurements are not taken within 3 minutes, the device resets all data on this patient and offers to take measurements anew. 65 Sources of information used in the preparation of the application: 1. Patent of the Russian Federation Mo2020867 MKY Ab185/05, Ab1N39/00, "Device for diagnostics", author: Kravchenko N.Ya.,

Rudoi I.Yu., application Mo5014556, dated November 26, 1991, publ. 15.10.94, Bull. Mo19, 2. As. USSR Mo1792641 MKY Ab185/05, "Device for pulse and electropuncture diagnostics", authors: S.Y. Klenov, A.P. Shibulkin, V.V. Lakin, V.V. Antonenko, application Mo4855473 dated 07/31/90, publ. . 07.02.93,

Bul. Mo5 (closest analog).

Claims (1)

Formula of the invention 70 A device for electropuncture diagnostics containing a microprocessor, an input limiter-converter, measuring electrodes, which is distinguished by the fact that it includes a memory device connected to the processor, a controlled switch of the measuring circuit connected to the processor, a sound emitter, software - controlled by the processor in accordance with the change of the measured value, graphic liquid crystal indicator connected to the output of the processor, controlled reference voltage source for measuring circuits, keyboard connected to the processor, infrared communication interface connected to the processor, controlled power supply connected to the elements of the circuit , and a real-time clock block. - with "c) "- " h- - s;" - sh» - about 50 IR e) p. 60 b5