KR102429722B1 - Ring type smart stethoscope having multi-channel - Google Patents

Abstract

The present invention relates to a multi-channel ring-type smart stethoscope, and in particular, to a multi-channel ring-type smart stethoscope configured as a ring type so that auscultation can be performed through multi-channels including electrocardiogram, pulse wave and cardiopulmonary sound, and can be used by attaching it to a finger. it's about

Description

Multi-channel ring-type smart stethoscope {RING TYPE SMART STETHOSCOPE HAVING MULTI-CHANNEL}

The present invention relates to a multi-channel ring-type smart stethoscope, and more particularly, a multi-channel ring-type stethoscope configured as a ring type so that auscultation can be performed through multi-channels including electrocardiogram, pulse wave and cardiopulmonary sound, while being mounted on a finger. It is about a smart stethoscope.

In general, a stethoscope is used to check whether the state is normal by listening to arterial, intestinal, and blood vessel sounds as well as heart and breathing sounds generated in the body. also do

Such a stethoscope is a digital stethoscope having a built-in microphone and a microcomputer, replacing the conventional analog stethoscope, and the digital stethoscope is used to analyze a stethoscope sound to enable precise examination or to be used for educational purposes.

However, the conventional stethoscope has a relatively simple function, so it cannot provide auscultation functions of several channels including electrocardiogram and pulse wave in addition to cardiopulmonary.

Republic of Korea Patent Registration No. 10-0986022 Republic of Korea Patent No. 10-1550676 Republic of Korea Patent No. 10-1436732

The present invention is to solve the problems described above, and while auscultation is possible through multi-channels including electrocardiogram, pulse wave and cardiopulmonary sound, a multi-channel ring-type smart stethoscope configured as a ring type so that it can be used by attaching it to a finger. would like to provide

To this end, the multi-channel ring-type smart stethoscope according to the present invention is to auscultate the human body (stethoscopy), and a ring-shaped body fitted to the user's finger; an electrocardiogram sensor installed on the ring-shaped body and measuring electrical activity of the heart; a pulse wave sensor installed on the ring-shaped body and measuring a change in blood flow due to heartbeat; a heart sound sensor installed on the ring-shaped body and measuring cardiopulmonary sound; and a power supply unit for supplying operating power to each of the sensors.

At this time, the ring-shaped body includes a hold portion fitted to the finger; a contact part connected to one side of the holding part and in close contact with the human body; and a communication interface for transmitting a sensor detection signal.

In addition, it is preferable that the holding part is configured to be fitted to the user's fingers of different thicknesses since it is formed in an open ring shape in which one side of the ring-shaped body is cut.

In addition, the electrocardiogram sensor may include a first electrode installed on the contact part; and a second electrode installed in the holding part; preferably, an electrocardiogram (ECG) is measured by the first electrode and the second electrode having opposite polarities.

In addition, it is preferable that the pulse wave sensor is a reflective pulse wave (PPG: Photo PlethysmoGraph) sensor that is installed in the hold part and measures a signal that is reflected and returned after the light source is transmitted through the skin.

In addition, the heart sound sensor is installed in the contact portion Simpe sound sensor for measuring the sound of Simpe; and a noise detection sensor installed in the contact part or the hold part to measure noise.

In addition, it is preferable that the cardiopulmonary sound sensor is installed at a lower end part of the contact part that directly contacts the human body, and the noise sensor is installed so as to face a space part outside the ring-shaped body from a side part that does not directly contact the human body among the contact parts. do.

In addition, a signal corresponding to at least a portion of the signal measured by the noise detection sensor from the signal measured by the cardiopulmonary sound sensor, the filtering unit further comprising a filtering unit for removing noise included in the cardiopulmonary sound through voice signal processing. It is desirable to remove the noise included in the cardiopulmonary sound by removing

In addition, a measurement start button provided on the ring-shaped body for generating a detection start signal as contact with the human body is made for auscultation; a switch for switching on a line transmitting a signal from the cardiopulmonary sound sensor to a filtering unit according to a detection start signal of the measurement start button; a buffer for storing the noise signal detected by the noise detection sensor from the time the stethoscope is powered on until the detection start signal is input; and a noise characteristic determining unit that analyzes any one or more of a frequency, a waveform pattern, and a magnitude of the noise signal provided from the buffer to analyze the characteristics of noise existing before the heart sound is measured; wherein the filtering unit further comprises: A comparison signal is generated by receiving the noise characteristic information provided by the noise characteristic determining unit, processing the noise signal detected by the noise detection sensor after the detection start signal, and generating a comparison signal from the signal measured by the cardiopulmonary sound sensor. It is preferable to remove the noise included in the cardiopulmonary sound by removing the comparison signal, which is the signal-processed noise.

In addition, the power supply unit includes a printed circuit board connected to each sensor through a circuit pattern; a secondary battery that supplies power to each of the sensors through a power line formed on the printed circuit board and is capable of charging and discharging; and a communication line for transmitting a detection signal from each of the sensors.

As described above, the present invention includes an electrocardiogram sensor, a pulse wave sensor and a heart sound sensor in a ring-shaped body. Therefore, it enables auscultation through multi-channels including electrocardiogram, pulse wave and cardiopulmonary sound. In addition, the ring-shaped body can be mounted on the finger to enable convenient use.

1 is a perspective view showing a multi-channel ring-type smart stethoscope according to the present invention.
2 is a state diagram of a multi-channel semi-type smart stethoscope according to the present invention.
3 is a cross-sectional view of a multi-channel semi-smart stethoscope according to the present invention.
4 is a diagram showing a sensing waveform of the multi-channel semi-type smart stethoscope according to the present invention.
5 is a diagram illustrating a filtering unit for removing noise according to the present invention.
6A and 6B are cross-sectional views of a multi-channel semi-smart stethoscope according to another embodiment of the present invention.
7 is a diagram illustrating a filtering unit for removing noise according to another embodiment of the present invention.
FIG. 8 is a noise removal timing diagram of FIG. 7 .

Hereinafter, a multi-channel ring-type smart stethoscope according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the multi-channel ring-type smart stethoscope 10 according to the present invention provides a ring-shaped body 11 including a ring-functioning body, that is, a ring shape, at least in part, and several stethoscopes sensors are installed.

The ring-shaped body 11 is exemplified to include a holding part 11a in which a finger is fitted, a contact part 11b in contact with the human body, and a communication interface 11c for transmitting a sensor signal.

The present invention puts a stethoscope on a finger as shown in FIG. 2 and enables auscultation of the human body in various postures lying or sitting as well as in a standing posture.

The ring-shaped body 11 includes an electrocardiogram sensor 12 , a pulse wave sensor 13 , and a heart sound sensor 14 . Therefore, it enables auscultation through a multi-channel including electrocardiogram, pulse wave, and cardiopulmonary sound, and enables the ring-shaped body 11 to be mounted on a finger for use.

3, the multi-channel ring-type smart stethoscope 10 according to the present invention supplies power to a ring-shaped body 11 for mounting on a finger, and several sensors 12, 13, 14 and sensors for auscultation. It includes a power supply unit (15). In this case, the sensors 12 , 13 , and 14 include an electrocardiogram sensor 12 , a pulse wave sensor 13 , and a heart sound sensor 14 .

In this configuration, the ring-shaped body 11 is a hold part 11a fitted to the user's finger, a contact part 11b connected to one side of the hold part 11a and in close contact with the human body, and a communication for transmitting a sensor detection signal and an interface 11c.

The holding part 11a is formed in a ring shape and is fitted to the finger of a user such as a doctor. Preferably, the holding part 11a has an open ring shape in which one side of the ring-shaped body is cut. Accordingly, it is possible to fit the user's fingers of different thicknesses.

The contact portion 11b is integrally molded or coupled to one side of the hold portion 11a, and as an embodiment, the lower end of the hold portion 11a to overcome the spatial limitation due to the installation of the sensor and increase the area in contact with the human body. It consists of a body of a square block provided in.

The communication interface 11c is configured in a wired manner including a signal line connected to the ring-shaped body 11 or is configured in a wireless manner such as a short-range wireless communication module, and provides the measured human body information to the examiner as shown in FIG. .

On the other hand, the electrocardiogram sensor 12 is installed in the ring-shaped body 11 to measure the electrical activity of the heart. According to the embodiment, the electrocardiogram sensor 12 may be installed to be exposed to the outside of the ring-shaped body 11 , but is preferably installed inside the ring-shaped body 11 .

The electrocardiogram sensor 12 includes a first electrode 12a installed in the contact portion 11b and a second electrode 12b installed in the hold portion 11a, and a first electrode 12a having opposite polarity to each other. An electrocardiogram (ECG) is measured by the and second electrode 12b.

For example, if the first electrode 12a is a positive (+) electrode, the second electrode 12b is configured as a negative (-) electrode. Of course, the first electrode 12a and the second electrode 12b are configured to have electrode polarities opposite to the above, so that an electric signal generated in the human body may be sensed.

However, the first electrode 12a is provided in the contact portion 11b that is in direct contact with the human body, and one electrode surface thereof is exposed through the lower surface of the contact portion 11b so as to contact the human body surface as much as possible, or is buried to a minimum shallow depth. can be

The pulse wave sensor 13 measures a change in blood flow due to heartbeat, that is, a pulse wave, and the pulse wave sensor 13 is also installed in the ring-shaped body 11 . As an embodiment, it is installed embedded in the ring-shaped body (110).

Specifically, the pulse wave sensor 13 is installed in the hold portion 11a of the ring-shaped body 11 into which a finger is fitted. The pulse wave sensor 13 is distributedly installed in the holding unit 11a in order to secure an installation space for other sensors, but is not limited thereto.

In addition, the pulse wave sensor 13 uses a reflective pulse wave (PPG: Photo PlethysmoGraph) sensor. The reflective pulse wave sensor 13 is a sensor to which a method of measuring a signal returned after a light source is transmitted through the skin is reflected.

For example, as the pulse wave sensor 13 includes a light emitting source and a light receiver, when light projected from the light source is irradiated to the human body, absorption of light occurs in blood, bone, and tissue, and some light is reflected and received by the receiver do.

The degree of light absorption is proportional to the amount of skin, tissue, and blood in the path through which the light passes, and does not change except for changes in blood flow caused by heartbeat, so that changes in blood flow can be measured with reflected light.

However, the electrocardiogram sensor 12 described above may be configured as a single sensor integrated with the pulse wave sensor 13 . That is, a single sensor may be configured as a multi-function sensor capable of measuring both an electrocardiogram and a pulse wave.

The heart sound sensor 14 is installed in the ring-shaped body 11 to measure cardiac sound. The heart sound sensor 14 is a kind of voice sensor, and measures including the sound generated by the heart apex (end of the heart) and the base of the heart generated during contraction/expansion of the heart.

In particular, the heart sound sensor 14 of the present invention has a noise canceling function. To this end, the heart sound sensor 14 includes two types of sensors including a cardiopulmonary sound sensor 14a for measuring heart sound and a noise sensor 14b for measuring noise.

At this time, the cardiopulmonary sound sensor 14a is installed in the contact part 11b to measure the heartbeat sound, and the noise sensor 14b is installed in the contact part 11b or the hold part 11a to measure noise. microphone is used. The measured noise is used to remove the noise included in the cardiopulmonary sound.

Preferably, the cardiopulmonary sound sensor 14a is installed at the lower end of the contact portion 11b in direct contact with the human body, and the noise sensor 14b is located at the side of the contact portion 11b that does not directly contact the human body. ) is installed to face the outer space.

Through this, the cardiopulmonary sound sensor 14a better measures the heart sound, and the noise sensor 14b accurately measures not only the noise outside the human body, but also the noise caused by the flow of blood or water other than the heart to be tested. be able to

Furthermore, the present invention further includes a filtering unit 14c as shown in FIG. 5 . The filtering unit 14c serves to remove noise included in the cardiopulmonary sound through voice signal processing.

Specifically, the filtering unit 14c may remove the noise included in the cardiopulmonary sound by removing a signal corresponding to at least a portion of the signal measured by the noise detection sensor 14b from the signal measured by the cardiopulmonary sound sensor 14a. have.

That is, it is possible to remove the noise measured at the time of measuring the heart sound by subtracting the noise signal from the signal-processed cardiopulmonary sound signal, etc., and to provide only the pure heart sound sound.

For example, in the case of a pregnant woman, if the heart sound of the baby in the womb is the test target, the mother's heart sound also corresponds to noise. Even in this case, the mother's heart sound sensed together with the baby's heart sound is removed, and only the baby's heart sound can be provided.

The filtering unit 14c may be configured in the form of a chipset in the ring-shaped body 11 or may be provided in an end terminal connected through the communication interface 11c, and the heart sound from which the noise is removed through filtering is output through an output unit such as a speaker ( 16) is provided. The output unit 16 may be an image output unit that displays an audio signal as a waveform or may also include an image output unit.

The power supply unit 15 supplies operating power to each sensor. That is, the power supply unit 15 supplies operating power required for signal detection in the electrocardiogram sensor 12 , the pulse wave sensor 13 , and the heart sound sensor 14 , and may include an electronic circuit for transmitting and receiving other signals.

Specifically, the power supply unit 15 supplies power to each sensor through a printed circuit board connected to each sensor through a circuit pattern, a power line formed on the printed circuit board, and a secondary battery capable of charging and discharging and in each sensor. and a communication line for transmitting a sensing signal, the communication line being connected to the communication interface.

This power supply unit 15 is installed in the hold portion 11a of the ring-shaped body 11 as an embodiment, and may further include a charging port for charging the secondary battery, that is, a charging port for charging the battery, or an opening/closing opening for replacing the secondary battery. can

On the other hand, as shown in FIGS. 6A and 6B , the present invention further includes a measurement start button 17 in order to provide a more precise and faster noise removal effect while removing noise from the heart sound as another embodiment. In addition, as shown in FIG. 7 , it further includes a switch 14d, a buffer 18, and a noise characteristic determining unit 19 to remove noise included in the heart sound together with the above-described filtering unit 14c.

The measurement start button 17 is provided on the ring-shaped body 11 and generates a detection start signal as contact with the human body is made for auscultation. For this purpose, FIG. 6A illustrates a push-button type measurement start button 17 protruding outward from the ring-shaped body 11 . 6B illustrates a short-circuit-type measurement start button 17 that generates a sensing start signal while conducting between the electrodes 17a and 17b as the human body contacts the two electrodes 17a and 17b spaced apart from each other.

As shown in FIG. 7 , the switch 14d switches on a line for transmitting a signal from the cardiopulmonary sound sensor to the filtering unit 14c according to the detection start signal of the measurement start button 17 . Through this, the heart sound is transmitted to the filtering unit 14c from the switching-on starting point.

The buffer 18 corresponds to a kind of data storage memory, from the time when power supply to the stethoscope is started by the power supply unit 15 until the detection start signal by the measurement start button 17 is inputted by the noise detection sensor 14b The detected noise signal is saved.

If the power supply by the power supply unit 15 is continued, ambient noise is recorded in the standby state, and when a separate power button is provided, noise is generated in the buffer 18 from the time when the user presses the power button and power starts to be supplied. It begins to be recorded.

The noise characteristic determining unit 19 analyzes any one or more of a frequency, a waveform pattern, and a magnitude of the noise signal provided from the buffer 18 to analyze the characteristics of noise existing before the heart sound is measured.

If the characteristics of the noise are analyzed in advance before the heart sound is supplied to the filtering unit 14c by the measurement start button 17, the noise and the heart sound are accurately and quickly distinguished. It makes it possible to remove noise and improve the removal effect.

In addition, in order to remove the noise detected together with the heart sound by the cardiopulmonary sound sensor 14a, it is possible to accurately provide a process for changing the size of the noise detected by the noise detection sensor 14b or a synchronization time point.

To this end, the filtering unit 14c receives the noise characteristic information provided from the noise characteristic determination unit 19 and processes the noise signal detected by the noise detection sensor 14b after the detection start signal to generate a comparison signal. do.

The comparison signal is obtained by processing the noise detected by the noise detection sensor 14b according to the processing standard selected by the noise characteristic determining unit 19 to remove the noise, and provides only the heart sound by subtracting the comparison signal from the heart sound containing such noise. make it possible

Accordingly, the noise included in the cardiopulmonary sound is removed by removing the comparison signal, which is the signal-processed noise, from the signal measured by the cardiopulmonary sound sensor 14a, and a user such as a doctor can only hear the heart sound of the test subject.

8 is a timing diagram in which the noise included in the heart sound is removed by the filtering unit 14c based on the measurement start button 17 as above. As shown, after power is supplied, noise for reading noise characteristics is collected, and after operation of the measurement start button 17, a heart sound is supplied, and at the same time, a measured noise is supplied to remove noise from the heart sound.

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations are possible within the scope that does not change the gist of the present invention. You will understand when you grow up.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention pertains the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

10: Ring-type smart stethoscope
11: Ring-shaped body
11a: hold part
11b: contact
11c: communication interface
12: electrocardiogram sensor
12a: first electrode
12b: second electrode
13: pulse wave sensor
14: heart sound sensor
14a: cardiopulmonary sound sensor
14b: noise detection sensor (14b)
14c: filtering unit
14d: switch (14d)
15: power supply
16: output unit (speaker, display)
17: Start measurement button
18: buffer (18)
19: noise characteristic determination unit (19)

Claims (10)

In a multi-channel ring-type smart stethoscope for stethoscopy of the human body,
a ring-shaped body 11 fitted to the user's finger;
an electrocardiogram sensor (12) installed on the ring-shaped body (11) and measuring the electrical activity of the heart;
a pulse wave sensor 13 installed on the ring-shaped body 11 and measuring a change in blood flow due to heartbeat;
a heart sound sensor 14 installed on the ring-shaped body 11 and measuring cardiopulmonary sound; and
and a power supply unit 15 for supplying operating power to each sensor.
The ring-shaped body 11,
a hold portion (11a) fitted to a finger;
a contact portion 11b connected to one side of the holding portion 11a and in close contact with the human body; and
Including; a communication interface (11c) for transmitting a sensor detection signal;
The heart sound sensor 14,
Simpe sound sensor installed in the contact portion (11b) to measure the sound Simpe; and
and a noise detection sensor 14b installed on the contact portion 11b or the hold portion 11a to measure noise;
Further comprising a filtering unit (14c) for removing the noise included in the cardiopulmonary sound through voice signal processing,
The filtering unit 14c removes the noise included in the cardiopulmonary sound by removing a signal corresponding to at least a part of the signal measured by the noise detection sensor 14b from the signal measured by the cardiopulmonary sound sensor 14a, ,
a measurement start button 17 provided on the ring-shaped body 11 and generating a detection start signal as contact with the human body is made for auscultation;
a switch 14d for switching on a line for transmitting a signal from the cardiopulmonary sound sensor to the filtering unit 14c according to the detection start signal of the measurement start button 17;
a buffer 18 (buffer) for storing the noise signal detected by the noise detection sensor 14b from when the stethoscope is powered on until the detection start signal is input; and
Further comprising; a noise characteristic determination unit 19 for analyzing the characteristics of noise existing before measuring the heart sound by analyzing any one or more of the frequency, waveform pattern, and magnitude of the noise signal provided from the buffer 18; and
The filtering unit 14c receives the noise characteristic information provided from the noise characteristic determination unit 19 and processes the noise signal detected by the noise detection sensor 14b after the detection start signal to obtain a comparison signal. The multi-channel ring-type smart stethoscope, characterized in that it removes the noise included in the cardiopulmonary sound by removing the comparison signal, which is the signal-processed noise, from the signal measured by the cardiopulmonary sound sensor (14a). delete According to claim 1,
The holding part 11a,
Multi-channel ring-type smart stethoscope, characterized in that it consists of an open ring shape in which one side of the ring-shaped body is cut, so that it can be fitted on the user's fingers of different thicknesses. According to claim 1,
The electrocardiogram sensor 12,
a first electrode 12a installed on the contact portion 11b; and
Including;
Multi-channel semi-type smart stethoscope, characterized in that the electrocardiogram (ECG) is measured by the first electrode (12a) and the second electrode (12b) having opposite polarities. According to claim 1,
The pulse wave sensor 13,
It is installed in the holding part (11a),
A multi-channel ring-type smart stethoscope, characterized in that it is a reflective pulse wave (PPG: Photo PlethysmoGraph) sensor that measures the reflected signal after the light source is transmitted through the skin. delete According to claim 1,
The cardiopulmonary sound sensor (14a) is installed at the lower end of the contact portion (11b) in direct contact with the human body,
The noise detection sensor (14b) is a multi-channel ring-type smart stethoscope, characterized in that it is installed so as to face the space outside the ring-shaped body (11) from the side that does not directly contact the human body of the contact portion (11b). delete delete According to claim 1,
The power supply unit 15,
a printed circuit board connected to each sensor through a circuit pattern;
a secondary battery that supplies power to each of the sensors through a power line formed on the printed circuit board and is capable of charging and discharging; and
Multi-channel semi-type smart stethoscope comprising a; communication line for transmitting the detection signal from each sensor.

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