KR100918575B1 - Multi-Vital Sign Wireless Monitoring System - Google Patents

Abstract

The present invention relates to a multi-biosignal wireless monitoring system, and more particularly, to a monitoring system for allowing a doctor to refer to a diagnosis of a patient by wireless monitoring of various bio-signals such as breath sounds, body temperature, and pulses generated from a patient. It is about.

The multi-body signal wireless monitoring system according to the present invention oscillates the voice signal or pulse signal of the sound generated by the human body collected by the sound collecting device, and the measured body temperature information obtained through the thermistor into an audible frequency signal and converts it into digital. A wireless side-side stethoscope that synthesizes the obtained digital body temperature signal, and then wirelessly modulates the synthesized signal by FM modulation;

FM detection of the modulated synthesized signal sent from the transmitting radiotelephone is performed to obtain a synthesized signal, and the synthesized signal is separated into a voice signal or a pulse signal and a body temperature signal for each frequency, and then the voice signal is output as sound. The signal and the pulse signal are configured to include a receiver-side radio stethoscope which outputs to each display unit numerically.

Wireless Stethoscope, Short Channel, Multi-display, Multi-Bio Signal (Breathing, Pulse, Body Temperature)

Description

Multi-Signal Wireless Monitoring System

The present invention relates to a multi-biosignal wireless monitoring system, and more particularly, to a monitoring system for allowing a doctor to refer to a diagnosis of a patient by wireless monitoring of various bio-signals such as breath sounds, body temperature, and pulses generated from a patient. It is about.

Stethoscopes collect sound from the organs inside the body, especially the heart or lungs, allowing the doctor to check the health of the subject.

The stethoscope consists of a sound collecting unit for collecting body sounds generated in the human body, an earpiece for listening to collected body sounds, and a tube for acoustically connecting the sound collecting unit and the earpiece.

The stethoscope is divided into mechanical and electronic, and the accuracy and reliability of the sound collected by the sound collector are very important variables for determining the physical condition of the medical person.

Mechanical stethoscopes are still widely used in the medical field, but they are increasingly being converted to digital electronic stethoscopes.

For example, an electronic stethoscope of Patent Publication No. 94-80, a portable electronic stethoscope of Utility Model Registration No. 204716, a stethoscope equipped with a microphone of Utility Model Registration No. 181469 are disclosed.

However, when a stethoscope is operated with a conventional mechanical or electronic stethoscope, it is difficult to detect minute changes in the heart sound and respiratory sound, and other people around cannot hear it at the same time, so that an objective judgment on the sound is impossible. Since the subjective judgment is followed, the false positive rate is relatively high, and when listening to the breathing sound with a conventional stethoscope, the intake and exhalation must be aused at least once in one position.

On the other hand, in particular, electronic stethoscopes have been attracting attention as telemedicine using communication networks has become common, and self-diagnostic digital stethoscopes of Korean Patent Publication No. 2002-95004 and methods of remote diagnosis using the communication network and US Visport of 2006-6118 The wireless digital stethoscope using the present invention relates to a technique for collecting a stethoscope sound at the transmitting side, converting it to digital, and transmitting the signal to the receiving side through wired / wireless communication to receive the signal at the receiving side and then perform signal processing and display the audiovisual visually.

However, the above-mentioned patent has no choice but to transmit and receive only one of the biological signals, the stethoscope sound, and thus, it is difficult to comprehensively grasp the physical state of the patient with reference to other biological signals.

In order to determine the physical state of the patient by referring to other living bodies, for example, body temperature or pulse, the configuration is complicated because the transmitting and receiving sides must be configured separately according to each biological signal such as body temperature or pulse. There was a problem that it takes a long time to measure and display the signal at the same time.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and transmits a radio frequency by transmitting and receiving breath, body temperature, pulse, etc. using a short channel FM frequency as a carrier so that a doctor can accurately determine the physical condition of the subject. It is an object of the present invention to provide a multi-biosignal wireless monitoring system that can simplify the configuration of a stethoscope and a receiver and reduce the time required for measuring and displaying various biosignals.

Multi-body signal wireless monitoring system according to the present invention for achieving the above object, the audio signal or pulse signal of the sound generated by the human body collected through the sound collecting device, and measured body temperature information obtained through the thermistor out of the audible frequency A transmitter-side wireless stethoscope which synthesizes a digital temperature signal obtained by oscillating into a signal and converting it to digital, and then FM-modulates the synthesized signal and transmits it wirelessly;

FM detection of the modulated synthesized signal sent from the transmitting radiotelephone is performed to obtain a synthesized signal, and the synthesized signal is separated into a voice signal or a pulse signal and a body temperature signal for each frequency, and then the voice signal is output as sound. The signal and the pulse signal are configured to include a receiver-side radio stethoscope which outputs to each display unit numerically.

According to the present invention, by using the FM frequency of a single channel as a carrier wave, wireless transmission and reception of body temperature, pulse rate, respiratory rate, and the like can simultaneously display various biological signals with a simple circuit configuration without using a CPU program.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

1 is a schematic configuration diagram of a biological signal monitoring system according to the present invention, FIG. 2 is a configuration diagram of a transmitter-side radio stethoscope shown in FIG. 1, and FIG. 3 is a configuration diagram of a receiver-side radio stethoscope shown in FIG.

As shown in the figure, the biosignal monitoring system is largely composed of a transmitter-side radio stethoscope 100 and a receiver-side radio stethoscope 200.

The transmitter-side wireless stethoscope 100 includes a sound collector 102, a preamplifier 104, a body temperature sensor 112, a voltage amplifier 114, an oscillator 116, an A / D converter 118, and a synthesis modulator. 120, the transmission antenna 130.

The sound collecting device 102 is composed of a microphone which soundproofed the external sound, and collects a voice signal or a pulse signal by collecting breath sounds of 60 to 10 kHz band or heart driving sound (pulse) of 60 to 200 Hz band.

The pre-amp 104 amplifies a weak voice signal or a pulse signal.

The body temperature sensor 112 is made of, for example, a thermistor whose resistance value is sensitive to changes in temperature, and measures the body temperature of a person.

The voltage amplifier 114 amplifies the voltage change due to body temperature, and the oscillator 116 generates an analog body temperature signal of 20 to 30 kHz, which is an audible frequency band outside the body temperature change of 33 ° C. to 43 ° C.

The A / D converter 118 converts an analog temperature signal of 20-30 Khz into a digital temperature signal.

The synthesis modulator 120 synthesizes a voice signal or a pulse signal and a body temperature signal, and transmits the synthesized signal of a low frequency to a 100 MHz carrier, for example, by oscillating into an FM frequency (high frequency) band and transmitting it through the transmission antenna 130.

If the modulated transmission of the frequency measured by the body temperature sensor 112 is changed to 20 ~ 30Khz, it is impossible to listen, so it can be used as a temperature display signal without affecting the listening using this point.

Since the transmitter-side wireless stethoscope 100 is used while being portable, it uses a rechargeable battery as a power source.

The reception side wireless stethoscope 200 includes a reception antenna 210, a high frequency amplifier 212, an FM detector 214, an amplifier 216, a frequency separator 218, a limit waveform corrector 232, 242, temperature The display converter 234, the counter 244, the display 236 and 246, the tone signal generator 238, the output amplifier 222 receiver 226, and the speakers 224 and 249.

The reception antenna 210 receives the modulated composite signal transmitted from the transmitting radio stethoscope 100.

The high frequency amplifier 212 amplifies a high frequency FM signal of the modulated composite signal received through the reception antenna 210, and the FM detector 214 rectifies a high frequency, for example, 100 MHz carrier to detect a low frequency synthesized signal. do.

The amplifier 216 amplifies the low frequency synthesized signal detected by the FM detector 214.

The frequency separator 218 separates, for example, a synthesized low frequency signal amplified by an equalizer for each frequency band, for example, a 60-200 hz pulse signal or a 20-30 kHz body temperature signal and a 60 hz to 10 kHz voice signal. do.

Separation of the pulse signal and the body temperature signal may be separated by pressing a button from the outside or may be separated by an internal equalizer circuit.

The equalizer separates five to twelve frequencies between the low and low ranges of 16 and the high range of 32, and increases or decreases the amplification of the sound with a very small width.

The voice signal is amplified by the output amplifier 222 and then output through the speaker 224 or the receiver 226 as a sound so that the doctor or the subject can hear.

The limit waveform correction unit 232 removes unnecessary noise components included in the body temperature signal of the 20 ~ 30Khz while undergoing wireless transmission and reception, and converts them into digital signals, and the temperature display converter 234 converts them into digital signals. The body temperature signal of the 20 ~ 30Khz frequency is converted into a digital temperature, which is displayed numerically on the display unit 236, such as a liquid crystal.

The limit waveform corrector 242 removes unnecessary noise components included in the 60-200 hz pulse signal while performing wireless transmission and reception, and converts the digital pulse signal into a digital pulse signal every 1 minute. Counting repeatedly (reset every 1 minute period), this digital pulse rate is displayed numerically on the display portion 246 of the liquid crystal.

The tone signal generator 248 generates a tone signal corresponding to the digital pulse signal so that the ear can hear it, and the pulse tone signal is output as sound through the speaker 249.

 The reception side wireless stethoscope 200 may be connected to the computer 300 to store and manage body temperature, pulse rate, breath sounds, etc. for each patient.

In the above configuration, the voice signal or pulse signal collected by the sound collecting device 102 is amplified by the preamplifier 104 and input to the synthesis modulator 120, and the body temperature signal measured by the body temperature sensor 112 is After voltage amplification and oscillation into an audible frequency signal according to a temperature change, the signal is converted into a digital signal and input to the synthesis modulator 120.

The voice signal or pulse signal and the body temperature signal are synthesized by the synthesis modulator 120 and FM-modulated to be transmitted through the transmission antenna 130.

The modulated synthesized signal is received through the reception antenna 210, amplified by a high frequency signal and demodulated into a synthesized signal, and then the demodulated synthesized signal is amplified again.

The amplified synthesized signal is divided into a voice signal, a pulse signal, or a body temperature signal for each frequency band, and the voice signal is amplified and output through the speaker 224.

The body temperature signal is converted into a digital signal from which noise components are removed and converted into a digital temperature, and displayed on the display unit 236 such as a liquid crystal as a number.

The pulse signal is converted into a digital signal from which a noise component is removed, and is counted every minute and displayed on the display unit 246 such as a liquid crystal as a number. The pulse signal is generated as a tone signal corresponding to the digital pulse rate, and is then transmitted through the speaker 249. The sound is output.

As described above, the present invention can display and transmit and transmit three elements (breath, pulse, and body temperature) by using one channel FM frequency (100Mhz in the present invention) as a carrier wave, and at least simply use a circuit without using a CPU program. Can be implemented.

In the above, the three elements of the biological signals have been described for breath sounds, pulses, and body temperature. However, the components such as respiratory rate and blood pressure can be synthesized by FM modulation and transmitted, and then wirelessly detected and detected by FM. It can also be implemented.

1 is a schematic configuration diagram of a biosignal monitoring system according to the present invention;

FIG. 2 is a configuration diagram of a transmitter-side radio stethoscope shown in FIG. 1;

3 is a block diagram of a receiver-side radio stethoscope shown in FIG.

<Description of the symbols for the main parts of the drawings>

100: transmitting side radio stethoscope 102: sound collector

112: body temperature sensor 120: synthetic modulator

200: receiver radio receiver 214: FM detector

218: frequency separation unit 232,242: limit waveform correction

236,246: display unit

Claims (3)

After synthesizing the audio signal or pulse signal of sound generated by the sound collecting device and the measured body temperature information obtained through the thermistor into an audible frequency signal and converting it into digital, the digital temperature signal obtained is synthesized. A transmitter-side radio stethoscope that FM-modulates a signal and transmits the signal wirelessly; FM detection of the modulated synthesized signal sent from the transmitting radiotelephone is performed to obtain a synthesized signal, and the synthesized signal is separated into a voice signal or a pulse signal and a body temperature signal for each frequency, and then the voice signal is output as sound. Multi-signal wireless monitoring system including a receiver wireless receiver that outputs the signal and the pulse signal to each display unit as a number. The method of claim 1, The wireless receiver is a sound collecting device for collecting a sound generated from the human body to obtain a voice signal or pulse signal, a preamplifier for amplifying the voice signal or pulse signal, a body temperature sensor for measuring the body temperature of the person, A voltage amplifier for amplifying a voltage change due to body temperature, an oscillator for generating an analog temperature signal in an audible frequency band due to the temperature change, an A / D converter for converting the analog temperature signal into a digital temperature signal, and the voice Composed of a signal or pulse signal and a body temperature signal synthesized by the FM modulator for transmitting to the transmission antenna, The receiver wireless receiver includes a high frequency amplifier for amplifying a high frequency signal of a modulated composite signal received through a receiving antenna, an FM detector for detecting only a low frequency synthesized signal among the modulated synthesized signals, and a low frequency detected by the FM detector. An amplifying unit for amplifying a synthesized signal, a voice signal or pulse signal that separates the amplified low frequency synthesized signal into signals for each frequency band, a frequency separation unit for separating the body temperature signal, an output amplifier for amplifying the voice signal, and A first speaker for outputting the voice signal amplified by the output amplifier as a sound, a first limit waveform correction unit for removing unnecessary noise components included in the body temperature signal and converting it into a digital signal, and an audible signal converted to the digital signal A temperature display converting unit for converting an out-of-frequency body temperature signal to a digital temperature, a first display unit for displaying the digital temperature numerically, A second limit waveform correction unit for removing unnecessary noise components included in the pulse signal and converting the digital signal into a digital signal, a counter for repeatedly counting the digital pulse signal at one minute intervals, and a number for displaying the counted digital pulse rate numerically. Multi-biosignal wireless monitoring system, characterized in that consisting of two display. The method of claim 2, And a tone signal generator for generating a tone signal corresponding to the digital pulse signal so as to hear the digital pulse signal by an ear, and a second speaker for outputting the pulse tone signal as a sound. Multi biosignal wireless monitoring system.

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