KR20060112885A - Arterial pulse detector - Google Patents

Abstract

An arterial pulse measuring system is provided to enhance accuracy of measured data by directly mounting a sensor module on a cuff, which is wound around an arm of a user. An arterial pulse measuring system includes an arterial pulse processor and a display portion. The arterial pulse processor detects an arterial pulse of a user by using a pressure sensor and processes the detected signal. The display displays the processed result. The arterial pulse processor includes a pressurizing portion, a circuit portion, and the display portion. Control and application programs are embedded in the circuit portion. The arterial pulse detected by the pressurizing portion is converted to a digital signal at an ADC(Analog Digital Converter). An MPU(MicroProcessor Unit) is controlled according to the application program. A power supply supplies power to the arterial pulse measuring system.

Description

Pulse wave measuring system {arterial pulse detector}

1 is a block diagram of a pulse wave system according to an embodiment of the present invention.

2 is a control circuit of the pulse wave system according to the present invention

3 is an algorithm of a pulse wave system according to the present invention;

Disclosed is a pulse wave system according to the present invention.

The present invention relates to a pulse wave system for diagnosing a pulse, and more particularly, to a pulse pulse generator capable of performing a more accurate true vein by measuring a sensor on a part to detect body pulse waves, such as the left and right arms of a subject.

In general, in oriental medicine, in order to determine the condition of a subject, the condition is diagnosed by a touch obtained by palpation (finger examination) at the wrist part of the subject. However, in this case, there may be an inaccurate diagnosis result due to sensory differences and career differences, which may lower the reliability of diagnosis.

In order to solve this problem, the pulse is recently diagnosed by a pulse rod equipped with a sensor, the diagnosis data is transmitted to the central processing unit, the diagnosis is judged by the central processing unit, and the diagnosis result is displayed through the display unit of the main unit of the pulse. A technique relating to a pulse generator is disclosed.

The present invention is a pulse wave measurement system for performing pulse wave measurement by measuring the pulse wave using a pressure sensor, a signal processing device, and an application program,

As a sensor used as an input to the device, a piezo sensor is used, and the output value of the pressure sensor generated during pulsation wave measurement can be measured at regular time intervals. In addition, the device has a form of medical equipment to be fixed installation type for easy use in the hospital.

The present invention corresponds to a medical device of oriental medicine, and the pulse and blood pressure are measured by measuring the period and intensity of the pulsating wave in veterinary medicine, and in the same way, the pulsating wave shape and By diagnosing characteristics, abnormalities in the body and symptoms of illness are determined. The method of measuring the pulsating wave in oriental medicine uses a method of diagnosing the pulsating wave by a doctor's finger pointing the pulsating point. Recently, various biometric instruments that can substitute for this method are developed and used. They are called pulses.

The most important part of the pulsator is the sensor device that directly detects the pulsation wave. The sensor device is one of input devices that allow a diagnoser to visually measure the shape and intensity of a pulsating wave through an electronic device by measuring the pulsating wave generated in a blood vessel as a result of repeating contraction / relaxation of the human heart. However, since the measurement of the pulsating wave requires precise signal measurement every week, accurate pulsating wave measurement is first of all necessary for the pulsator to obtain a correct measurement result.

Two problems must be solved to measure accurate pulsations. One is the question of how to find the exact pulse point and contact the sensor, and the other is how to maintain a constant measurement condition while the pulsation measurement is repeated. Recently, many advances have been made in the electronic device and the sensor device of the pulse device due to the development of various electronic technologies, which help to develop a more sophisticated pulse device. There are many advances in the sensor mechanism, such as the use of electric motors and sophisticated mechanisms in the sensor device to pinpoint the peaks or find the maximum point of the signal. However, the sensor devices used in the conventional pulse generators are very difficult to determine that the measured signals are measured under uniform conditions even if the exact measurement site is found. Although most pulsators use a method of applying pressure near the sensor using pressure bars and pneumatics to bring the pressure sensor close to the pulsation under the same conditions and conditions as possible, the pulse wave measurement process through the pressure sensor itself is very Because of the delicate measurement of weak signals, even slight changes in pressure have a significant effect on the measurement results. Therefore, even when repeated measurements on the same measurement site are repeated for the same patient, It is not possible to guarantee that the pressure conditions applied to the blood pressure sensor at each measurement are the same only because of changes in muscle position.

Therefore, in order to solve this problem, the present invention installs the measuring circuit and the device in the fixed frame in order to increase the stability of the measuring device as much as possible and to perform a uniform sensor measurement. This minimizes external electromagnetic interference or signal distortion, and enables the patient to take measurements in a stable state, enabling accurate pulse wave measurement.

When explaining the present invention in detail by the accompanying drawings for achieving the above object,

1 is a configuration diagram of a pulse wave system of an embodiment according to the present invention;

2 is a control circuit diagram of a pulse wave system according to the present invention;

3 is an algorithm of the pulse wave system according to the present invention.

As shown in FIG. 1, the sensor module includes a sensor module and a pulse wave processing device. The sensor module is composed of a single pressure sensor, which is generally used in a pulse generator, and is connected to a pulse wave processing device through a signal connection line. The sensor module is mounted directly on the compression bar and is intended to be connected to the pneumatic device in the pulse wave measuring device.

The pulse wave processing device is comprised of a circuit part, a display part, and a pneumatic device. The circuit unit receives the pressure sensor signal and the pneumatic sensor signal transmitted from the sensor module through the signal connection line, performs analog-to-digital (A-D) conversion, generates pulse wave data, processes it, and displays the result on the display unit. The display unit is composed of an LCD display and a switch panel which display data or control steps displayed by the pulse wave detector. The pneumatic device is composed of a presser to fix the sensor module, a pneumatic motor to apply air pressure to the presser, a pneumatic tube, an exhauster to discharge air, and a driver circuit to electrically drive them.

MPUs and memories in the circuitry have embedded applications that perform pulse wave measurements. The pulse wave data measured by the application is processed through a filter and signal stabilization program, and the measured pulse wave data is displayed on the screen panel in the form of graphs and text.

The operation is started by attaching the pneumatic bar including the sensor module to the measurement site of the patient and adding the power of the device to perform the pulse wave measurement process determined by the application program stored in the internal memory.

When the unit is operated, the pneumatic device is operated first. The pneumatic device starts to pressurize the air to the pressure zone with the pressure sensor and stops when a certain level of pressure is applied. When the air is pressurized, the MPU starts to measure the pressure sensor's value at regular intervals, and each time the measured value is converted into pulse wave data through analog-to-digital conversion and control and transmitted to the application in real time. Is continued until the measurement is finished. The application program processes the pulse wave data and outputs the result of text and graphs on the screen. 3 shows an operation process of such a pulse wave measuring system.

As described above, the present invention guarantees measurement stability, uniformity of measurement data, and can be easily used.

In addition, the examinee makes an accurate diagnosis using the pulse wave system of the present invention, and since the diagnosed data can be transmitted and stored in the memory unit and transmitted to the examinee using communication with the display device, the examinee can check the health diagnosis at a long distance. There is convenience to receive.

Claims (2)

In the pulse wave system for measuring the pulse wave of the examinee, A pulse wave system comprising a pulse wave processing device and a display unit for detecting a pulse wave of an examinee with a pressure target and processing the detected signal. The method according to claim 1, The pulse wave processing device comprises a pneumatic device, a circuit part and a display part; The circuit portion is characterized in that the pulse wave system is operated as a control / application program.

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