KR20200129791A - Patch type monitoring device and method capable of measuring heartbeat and respiration - Google Patents

Abstract

Provided is a patch type monitoring device including: a piezoelectric unit generating an electric signal according to vibration; a patch unit transmitting vibration to the piezoelectric unit; an electrode unit for transmitting an electric signal; and a control unit which receives the electrical signal to detect a heart rate signal or a respiration signal, receives an electrical signal from the electrode unit and another electrode unit to detect at least one of the heart rate signal or the respiration signal, and corrects the heart rate signal or the breathing signal by comparing the detected plurality of heart rate signals or respiration signals.

Description

Patch type monitoring device and method capable of measuring heartbeat and respiration}

The present invention relates to a patch-type monitoring device and method capable of measuring heart rate and respiration, and more particularly, to a patch-type monitoring device and method for measuring vibration generated from a user's heart rate and respiration using a piezoelectric sensor. will be.

In the modern society, there is a growing demand for a technology that can check biometric information in real time for various reasons related to heart disease such as high blood pressure and diabetes.

As a conventional method of measuring heart rate, a technique has been developed in which sound signals appearing from a living body can be directly observed using a diaphragm. However, the method of using the diaphragm has a disadvantage of being unstable because the medical personnel directly hears the sound signal transmitted from the diaphragm and judges it according to the senses.

In addition, an echocardiography technique capable of imaging and analyzing the inside of the body by using ultrasound has been developed, but this leads to the use of expensive equipment that is difficult to use in everyday life.

Meanwhile, a technology for measuring blood flow using an optical sensor and measuring heart rate through it has been developed. However, the method using the optical sensor has a disadvantage in that the heart rate may be measured irregularly.

Accordingly, there is a need for a bio-signal measuring device that is convenient to use in daily life and has high reliability.

The technical problem to be solved by the present invention is to provide a patch-type monitoring device and method capable of measuring heart rate and respiration.

One aspect of the present invention, a piezoelectric unit for generating an electric signal according to the vibration; A patch part positioned above and below the piezoelectric part to transmit vibration to the piezoelectric part; An electrode part having one end connected to the piezoelectric part and adjacent to the patch part to transmit an electric signal generated from the piezoelectric part; Receiving the electrical signal to detect at least one of a heart rate signal or a respiration signal, receiving an electrical signal from the electrode unit and another electrode unit to detect at least one of a heart rate signal or a respiration signal, and a plurality of detected heart rate signals or It includes a control unit for compensating the heart rate signal or the breathing signal by comparing the breathing signal.

In addition, the electrode unit may include a first upper electrode unit positioned above the piezoelectric unit; A second upper electrode part positioned above the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a different path from the first upper electrode part; A first lower electrode part positioned below the piezoelectric part; And a second lower electrode part positioned below the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a different path from the first lower electrode part.

In addition, the controller calculates an upper correction signal from the electrical signal transmitted from the first upper electrode part and the second upper electrode part, and the first lower electrode part and the second lower electrode part. The lower correction signal can be calculated from the electrical signal.

In addition, the control unit generates a first detection signal by detecting at least one of the heartbeat signal or the respiration signal from the electric signal transmitted through the first upper electrode unit and the first lower electrode unit, and the second At least one of the heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electrical signal transmitted through the upper electrode part and the second lower electrode part The first detection signal is detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the first upper electrode part and the second lower electrode part to generate a second detection signal. Generates a third detection signal by detecting at least one of the heartbeat signal or the breathing signal identical to the detection signal, and the first upper electrode from the electrical signal transmitted through the second upper electrode part and the first lower electrode part A fourth detection signal is generated by detecting at least one of the heartbeat signal or the respiration signal identical to the first detection signal detected from the part and the first lower electrode part, and the first detection signal and the second detection signal , An average value of the third detection signal and the fourth detection signal may be calculated.

In addition, the control unit generates a fifth detection signal by detecting at least one of the heartbeat signal or the respiration signal from the electric signal transmitted through the first upper electrode unit and the first lower electrode unit, and the second The sixth detection signal may be generated by detecting at least one of the heartbeat signal or the respiration signal different from the fifth detection signal from the electrical signal transmitted through the upper electrode part and the second lower electrode part.

In addition, the controller detects at least one of the heartbeat signal or the respiration signal identical to the fifth detection signal from the electrical signal transmitted through the first upper electrode part and the second lower electrode part to detect a seventh detection signal And generating an eighth detection signal by detecting at least one of the heartbeat signal or the respiration signal identical to the sixth detection signal from the electric signal transmitted through the second upper electrode part and the first lower electrode part can do.

Also, the controller may generate a first correction signal from the fifth detection signal and the seventh detection signal, and generate a second correction signal from the sixth detection signal and the eighth detection signal.

In addition, the control unit receives the electrical signal from the piezoelectric unit, separates the electrical signal into different frequency bands, analyzes the electrical signal separated into the frequency band, and analyzes at least one of the heartbeat signal or the breathing signal. Can detect one.

In addition, the patch part may include an upper patch part positioned above the piezoelectric part; And a lower patch part positioned under the piezoelectric part, wherein the upper patch part is coupled to the lower patch part to cover at least one of the piezoelectric part, the patch part, the electrode part, the control part, and the output part. Can be configured.

Another aspect of the present invention is a device attaching step of bonding the adhesive surface to the user's skin; A piezoelectric detection step of detecting a vibration generated by the piezoelectric unit from the outside from the adhesive surface and generating an electric signal from the vibration; An electric signal transmission step of transferring the electric signal along an electrode portion electrically connected to the piezoelectric unit; Receiving the electrical signal to detect at least one of a heart rate signal or a respiration signal, and by receiving an electrical signal from the electrode unit and another electrode unit receiving the electrical signal to detect at least one of a heart rate signal or a respiration signal, and detect Compensating the heart rate signal or the breathing signal by comparing the plurality of heart rate signals or respiration signals.

In addition, the heart rate and respiration detecting step may include: a first upper electrode part positioned above the piezoelectric part; A second upper electrode part positioned above the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a different path from the first upper electrode part; A first lower electrode part positioned below the piezoelectric part; And a second lower electrode part positioned below the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a different path from the first lower electrode part.

In addition, the heart rate and respiration detection step may include calculating an upper correction signal from the electric signal transmitted from the first upper electrode part and the second upper electrode part, and the first lower electrode part and the second lower electrode part It is possible to calculate a lower correction signal from the electrical signal transmitted from.

In addition, the heart rate and respiration detection step may generate a first detection signal by detecting at least one of the heart rate signal or the respiration signal from the electrical signal transmitted through the first upper electrode part and the first lower electrode part, and , The heart rate signal or the respiration identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the second upper electrode part and the second lower electrode part Detects at least one of the signals to generate a second detection signal, and detects from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the first upper electrode part and the second lower electrode part To generate a third detection signal by detecting at least one of the heartbeat signal or the breathing signal that is the same as the first detection signal, and from the electrical signal transmitted through the second upper electrode part and the first lower electrode part, the A fourth detection signal is generated by detecting at least one of the heartbeat signal or the respiration signal that is the same as the first detection signal detected from the first upper electrode part and the first lower electrode part, and the first detection signal, the An average value of the second detection signal, the third detection signal, and the fourth detection signal may be calculated.

In addition, the heart rate and respiration detection step may generate a fifth detection signal by detecting at least one of the heart rate signal or the respiration signal from the electrical signal transmitted through the first upper electrode part and the first lower electrode part, and , It is possible to generate a sixth detection signal by detecting at least one of the heartbeat signal or the breathing signal different from the fifth detection signal from the electrical signal transmitted through the second upper electrode part and the second lower electrode part. .

In addition, the heart rate and respiration detection step, by detecting at least one of the same heart rate signal or the respiration signal as the fifth detection signal from the electrical signal transmitted through the first upper electrode part and the second lower electrode part A seventh detection signal is generated, and an eighth by detecting at least one of the heartbeat signal or the respiration signal identical to the sixth detection signal from the electric signal transmitted through the second upper electrode part and the first lower electrode part. A detection signal may be generated, a first correction signal may be generated from the fifth detection signal and the seventh detection signal, and a second correction signal may be generated from the sixth detection signal and the eighth detection signal.

According to one aspect of the present invention described above, by providing a patch-type monitoring device and method capable of simultaneously measuring heart rate and respiration that are conveniently attached to the body, the user's heart rate and respiration are easily monitored and related to heart rate and respiration. You can prevent emergencies and respond quickly.

1 is a perspective view of a patch type monitoring device according to an embodiment.
2 is a perspective view of a patch type monitoring device in which an electrode part is modified according to an exemplary embodiment.
3 is a flowchart of a method for monitoring a patch type according to an exemplary embodiment.

DETAILED DESCRIPTION OF THE INVENTION The detailed description of the present invention to be described below refers to the accompanying drawings, which illustrate specific embodiments in which the present invention may be practiced. These embodiments are described in detail sufficient to enable a person skilled in the art to practice the present invention. It is to be understood that the various embodiments of the present invention are different from each other but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description to be described below is not intended to be taken in a limiting sense, and the scope of the present invention, if appropriately described, is limited only by the appended claims, along with all ranges equivalent to those claimed by the claims. In the drawings, like reference numerals refer to the same or similar functions over several aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a perspective view of a patch type monitoring device according to an embodiment.

The patch type monitoring device 100 includes a piezoelectric unit 110 that generates an electric signal according to vibration, a patch unit 120 positioned above and below the piezoelectric unit 110 to transmit vibration to the piezoelectric unit 110, One end is connected to the piezoelectric unit 110, the electrode unit 130 for transmitting an electric signal generated from the piezoelectric unit 110 adjacent to the patch unit 120, and detects a heart rate signal or a breathing signal by receiving the electric signal It may include a control unit 140.

The piezoelectric unit 110 may detect vertical vibration or left and right vibration generated from the user's heartbeat or breathing. In this case, the vertical vibration or left and right vibration detected by the piezoelectric unit 110 may be detected from the user's skin. In addition, the piezoelectric unit 110 may detect diagonal vibrations in which vertical vibrations and left and right vibrations are combined.

The piezoelectric unit 110 may generate an electric signal from the detected vibration. In this case, the electric signal may appear in a different waveform depending on the magnitude and period of the vibration. Accordingly, the patch type monitoring device 100 may detect a heart rate signal or a respiration signal according to the characteristics of the electrical signal.

The patch portion 120 may include an upper patch portion 120b positioned above the piezoelectric portion 110 and a lower patch portion 120a positioned below the piezoelectric portion 110.

The upper patch part 120b may have a shape covering the piezoelectric part 110, the electrode part 130, the control part 140, and the output part. In this case, the upper patch portion 120b may be coupled to the lower patch portion 120a. In addition, the upper patch part 120b may include an insulating material, and accordingly, the patch-type monitoring device 100 may be electrically insulated from the outside.

The lower patch part 120a may vibrate according to heartbeat vibration and breathing vibration transmitted to the user's skin. Through this, the lower patch part 120a may transmit heartbeat vibration and breathing vibration to the piezoelectric part 110.

The lower patch part 120a may be attached to the user's skin. To this end, the lower patch portion 120a may include an adhesive surface on one side. In this case, the lower patch portion 120a may include a protective surface for protecting the adhesiveness of the adhesive surface.

The electrode unit 130 may transmit an electric signal to the control unit 140. In addition, the electrode unit 130 may include an upper electrode unit 130b positioned above the piezoelectric unit 110 and a lower electrode unit 130a positioned below the piezoelectric unit 110. In this case, the electrode unit 130 may transmit an electric signal generated in a pattern such as vertical vibration, left and right vibration, and diagonal vibration from the piezoelectric unit 110 according to the configuration. In FIG. 1, an exemplary embodiment in which the electrode unit 130 is composed of an upper electrode unit 130b and a lower electrode unit 130a and transmits an electric signal generated from vertical vibration will be described.

The upper electrode unit 130b may electrically connect the upper side of the piezoelectric unit 110 and one side of the control unit 140. In addition, the lower electrode unit 130a may electrically connect the lower side of the piezoelectric unit 110 and the other side of the control unit 140.

The controller 140 may receive an electric signal from the piezoelectric unit 110. In this case, the electric signal may be transmitted through the electrode unit 130, and the electrode unit 130 may include an upper electrode unit 130b and a lower electrode unit 130a.

The controller 140 may detect a heartbeat frequency range measured from the human heartbeat from the electrical signal, and the controller 140 may detect a breathing frequency range measured from the human breath from the electrical signal.

The patch type monitoring device 100 may include an output unit that outputs a heart rate signal and a respiration signal detected by the control unit 140. The output unit may be added to the patch time monitoring apparatus 100 in various forms, but the present invention is not limited by this exemplary embodiment. For example, the output unit may be located on one side of the upper electrode unit 130b. In addition, the output unit may be located on one side of the upper patch unit 120b.

The output unit may output a heart rate signal and a respiration signal. In this case, the output unit may simultaneously output a heart rate signal and a respiration signal.

The output unit may output a notification when the frequency of the heart rate signal and the respiration signal exceeds a preset maximum frequency or is lower than a preset minimum frequency. In this case, the highest frequency or lowest frequency may be a frequency that can be determined as a dangerous state for human heart rate or breathing.

The output unit may output a notification in the form of sound, vibration, or light emission.

2 is a perspective view of a patch type monitoring device in which an electrode part is modified according to an exemplary embodiment.

Parts not specifically mentioned in FIG. 2 may be described through FIG. 1.

The patch type monitoring device 100 is located on the upper and lower sides of the piezoelectric unit 110, the piezoelectric unit 110 for detecting vibrations generated from heartbeat and respiration and transmitted to the skin, and generating electrical signals according to the detected vibrations. , The patch unit 120 attached to the user's body, the electrode unit 130 for transmitting an electric signal generated from the piezoelectric unit 110, the control unit 140 for detecting a heart rate signal or a breathing signal by receiving the electric signal Can include.

The piezoelectric unit 110 may detect vertical vibration, left and right vibration, and diagonal vibration transmitted from the heartbeat or breath to the skin. To this end, the electrode unit 130 may be positioned at the upper left, lower left, upper right, and lower right of the piezoelectric unit 110.

The upper patch part 120b may have a shape covering the piezoelectric part 110, the electrode part 130, the control part 140, and the output part. In this case, the upper patch part 120b may include a material that electrically insulates the first upper electrode part 131 and the second upper electrode part 133. Through this, the first upper electrode part 131 and the second upper electrode part 133 may transmit different electrical signals.

The lower patch part 120a may include a material that electrically insulates the first lower electrode part 132 and the second lower electrode part 133. Through this, the first lower electrode unit 132 and the second lower electrode unit 133 may transmit different electrical signals.

The electrode unit 130 may include a first upper electrode unit 131 and a second upper electrode unit 133 electrically connected from the upper side of the piezoelectric unit 110. In addition, the electrode unit 130 may include a first lower electrode unit 132 and a second lower electrode unit 134 electrically connected to the lower side of the piezoelectric unit 110.

The first upper electrode part 131, the first lower electrode part 132, the second upper electrode part 133, and the second lower electrode part 134 may be electrically connected to different side surfaces of the control unit 140. have. Accordingly, the first upper electrode part 131, the first lower electrode part 132, the second upper electrode part 133, and the second lower electrode part 134 transmit electric signals through different paths. ).

Meanwhile, in FIG. 2, the control unit 140 may be determined to be located on both sides of the piezoelectric unit 110, but in the practice of the present invention, the control unit 140 may appear in a different form. For example, the control unit 140 may surround the piezoelectric unit 110 with one side open. As another example, the control unit 140 may surround the piezoelectric unit 110 in a form in which all surfaces are closed. Accordingly, the shape of the control unit 140 is not limited by the exemplary embodiment of the present invention.

The controller 140 may generate an upper correction signal. In this case, the upper correction signal may be an average value of electric signals transmitted through the first upper electrode part 131 and the second upper electrode part 133. Further, the upper correction signal can be calculated from the electrical signal generated at the same instant. Accordingly, the control unit 140 may calculate a more accurate electrical signal from the first upper electrode unit 131 and the second upper electrode unit 132.

The controller 140 may generate a lower correction signal. In this case, the lower correction signal may be an average value of electric signals transmitted through the first lower electrode unit 132 and the second lower electrode unit 134. In addition, the lower correction signal can be calculated from the electrical signal generated at the same moment. Accordingly, the control unit 140 may calculate a more accurate electrical signal from the first lower electrode unit 132 and the second lower electrode unit 134.

Meanwhile, when the electric signal transmitted from the electrode unit 130 at one side exists outside the allowable range, the controller 140 may determine the electric signal as an erroneous electric signal. In this case, the erroneous electric signal may be replaced with an electric signal transmitted from the other electrode unit 130, and the replaced electric signal may be a signal transmitted by one electrode unit 130, which is the same as the erroneous electric signal of the upper or lower side. . For example, when the electric signal received from the first upper electrode part 131 is an erroneous electric signal, the erroneous electric signal may be replaced with the electric signal received from the second upper electrode part 133.

The control unit 140 may receive an electrical signal from the first upper electrode unit 131 and the first lower electrode unit 132, and detects one of a heart rate signal or a respiration signal as a first detection signal through the electric signal. can do.

The controller 140 may receive an electric signal from the second upper electrode unit 133 and the second lower electrode unit 134, and detect the same signal as the first detection signal as a second detection signal through the electric signal. can do.

The control unit 140 may receive an electric signal from the first upper electrode unit 131 and the second lower electrode unit 134, and detect the same signal as the first detection signal as a third detection signal through the electric signal. can do.

The controller 140 may receive an electric signal from the second upper electrode unit 133 and the first lower electrode unit 132, and detect the same signal as the first detection signal as a fourth detection signal through the electric signal. can do.

The controller 140 may detect a heart rate signal or a respiration signal with improved accuracy by calculating an average value of the first detection signal, the second detection signal, the third detection signal, and the fourth detection signal.

The controller 140 may calculate an average value with only some detection signals according to the state of the signal. At this time, the state of the signal may be related to the erroneous electrical signal. For example, when the electric signal received from the first upper electrode unit 131 is determined to be an erroneous electric signal, the accuracy of the detection signal may be improved by calculating an average value of the second detection signal and the fourth detection signal. .

The controller 140 may detect one of a heart rate signal or a respiration signal from the first upper electrode unit 131 and the first lower electrode unit 133 as a fifth detection signal.

The controller 140 may detect one of a heartbeat signal or a respiration signal different from the fifth detection signal from the second upper electrode part 131 and the second lower electrode part 134 as the sixth detection signal.

The controller 140 may detect the same signal as the fifth detection signal from the first upper electrode part 131 and the second lower electrode part 134 as the seventh detection signal.

The controller 140 may detect the same signal as the sixth detection signal from the second upper electrode part 133 and the first lower electrode part 132 as the eighth detection signal.

The controller 140 may generate a first correction signal or a second correction signal. The first correction signal may be an average value of the fifth detection signal and the seventh detection signal, and the second correction signal may be an average value of the sixth detection signal and the eighth detection signal. Through this, the patch-type monitoring device 100 may correct the heart rate signal and the respiration signal, respectively.

The patch type monitoring apparatus 100 may include an output unit capable of simultaneously outputting two corrected signals. The output unit may be added to the patch type monitoring device 100 in various forms, but the present invention is not limited by this embodiment.

3 is a flowchart of a method for monitoring a patch type according to an exemplary embodiment.

The patch type monitoring method includes a device attaching step 500 of bonding the adhesive surface to the user's skin, a piezoelectric detection step in which the piezoelectric unit 110 detects vibration generated from the outside from the adhesive surface, and generates an electric signal from the vibration ( 510), an electrical signal transmission step 520 of transmitting an electrical signal along the electrode unit 130 connected to the piezoelectric part 110, a heart rate and respiration detection step of detecting a heart rate signal or a respiration signal by receiving the electrical signal ( 530) may be included.

The device attachment step 500 may be a step in which the lower patch portion 120a is attached to the user's skin. In addition, as the lower patch portion 120a includes the protective surface, the step of removing the protective surface may be included.

On the other hand, the patch type monitoring device 100 may monitor heart rate and respiration by attaching it near the heart or near the artery.

The piezoelectric detection step 510 may be a step in which the piezoelectric unit 110 detects heartbeat vibration and respiratory vibration transmitted to the skin. To this end, the patch unit 120 may transmit the vibration transmitted to the skin to the piezoelectric unit 110.

The electrical signal transmission step 520 may be a step of transmitting an electrical signal for heartbeat vibration and respiratory vibration generated by the piezoelectric unit 110 to the controller 140. In this case, the electric signal may be transmitted from the piezoelectric unit 110 to the control unit 140 through the electrode unit 130.

Heart rate and respiration detection step 530 may detect electrical signals for each frequency. In this case, the frequency may include a heart rate signal or a respiration signal. Here, the heart rate signal may include a frequency range that can be measured from a human heartbeat, and the respiration signal may include a frequency range that can be measured from a human breath.

The heart rate and respiration detection step 530 may transmit an electrical signal to the controller 140 through different paths electrically separated from the piezoelectric unit 110. In this case, different paths may be the first upper electrode part 131, the first lower electrode part 132, the second upper electrode part 133, and the second lower electrode part 134.

Heart rate and respiration detection step 530 may generate an upper correction signal. In this case, the upper correction signal may be an average value of electric signals transmitted through the first upper electrode part 131 and the second upper electrode part 133. Further, the upper correction signal can be calculated from the electrical signal generated at the same instant. Accordingly, the heart rate and respiration detection step 530 may calculate more accurate electrical signals from the first upper electrode part 131 and the second upper electrode part 132.

Heart rate and respiration detection step 530 may generate a lower correction signal. In this case, the lower correction signal may be an average value of electric signals transmitted through the first lower electrode unit 132 and the second lower electrode unit 134. In addition, the lower correction signal can be calculated from the electrical signal generated at the same moment. Accordingly, the heart rate and respiration detection step 530 may calculate a more accurate electrical signal from the first lower electrode unit 132 and the second lower electrode unit 134.

Meanwhile, in the heart rate and respiration detection step 530, when the electrical signal transmitted from the electrode unit 130 of one side exists outside the allowable range, the electrical signal may be determined as an error electrical signal. In this case, the erroneous electrical signal may be replaced with an electrical signal transmitted from the other electrode unit 130, and the replaced electrical signal may be a signal included in the same category as the erroneous electrical signal of the upper or lower side. For example, when the electric signal received from the first upper electrode part 131 is an erroneous electric signal, the erroneous electric signal may be replaced with the electric signal received from the second upper electrode part 133.

Heart rate and respiration detection step 530 may receive electrical signals from the first upper electrode unit 131 and the first lower electrode unit 132, and first detect one of a heart rate signal or a respiration signal through the electrical signal. As a signal, it can be detected.

Heart rate and respiration detection step 530 may receive an electric signal from the second upper electrode unit 133 and the second lower electrode unit 134, and the second detection of the same signal as the first detection signal through the electric signal As a signal, it can be detected.

Heart rate and respiration detection step 530 may receive an electrical signal from the first upper electrode part 131 and the second lower electrode part 134, and a third detection of the same signal as the first detection signal through the electrical signal. As a signal, it can be detected.

Heart rate and respiration detection step 530 may receive electrical signals from the second upper electrode unit 133 and the first lower electrode unit 132, and detect a fourth signal that is the same as the first detection signal through the electric signal. As a signal, it can be detected.

The heart rate and respiration detection step 530 may detect a heart rate signal or respiration signal with improved accuracy by calculating an average value of the first detection signal, the second detection signal, the third detection signal, and the fourth detection signal.

Heart rate and respiration detection step 530 may calculate an average value only with some detection signals according to the state of the signal. At this time, the state of the signal may be related to the erroneous electrical signal. For example, when the electric signal received from the first upper electrode unit 131 is determined to be an erroneous electric signal, the accuracy of the detection signal may be improved by calculating an average value of the second detection signal and the fourth detection signal. .

The heart rate and respiration detection step 530 may detect one of a heart rate signal or a respiration signal from the first upper electrode unit 131 and the first lower electrode unit 133 as a fifth detection signal.

The heart rate and respiration detection step 530 may detect one of the fifth detection signal and other heart rate signal or respiration signal from the second upper electrode part 131 and the second lower electrode part 134 as a sixth detection signal. have.

The heart rate and respiration detection step 530 may detect the same signal as the fifth detection signal from the first upper electrode part 131 and the second lower electrode part 134 as a seventh detection signal.

The heart rate and respiration detection step 530 may detect the same signal as the sixth detection signal from the second upper electrode unit 133 and the first lower electrode unit 132 as the eighth detection signal.

Heart rate and respiration detection step 530 may generate a first correction signal or a second correction signal. The first correction signal may be an average value of the fifth detection signal and the seventh detection signal, and the second correction signal may be an average value of the sixth detection signal and the eighth detection signal.

The patch type monitoring method may include a heart rate and breath output step of outputting a heart rate signal or a breath signal detected in the heart rate and breath detection step 530. However, the present invention is not limited by this embodiment.

The heart rate and respiration output step may output a heart rate signal and a respiration signal. At this time, the heart rate and respiration output step may output a heart rate signal and a respiration signal through an electrically separated path, thereby simultaneously outputting a heart rate signal and a respiration signal.

The heart rate and respiration output step may output a notification when the frequency of the heart rate signal and the respiration signal exceeds a preset maximum frequency or is lower than a preset minimum frequency. At this time, the notification may be output in the form of sound, vibration, or light emission.

100: patch type monitoring device
110: piezoelectric part
120: patch part
120a: lower patch portion
120b: upper patch portion
130: electrode part
130a: lower electrode part
130b: upper electrode portion
131: first upper electrode part
132: first lower electrode part
133: second upper electrode part
134: second lower electrode portion
140: control unit

Claims (15)

A piezoelectric unit generating an electric signal according to the vibration;
A patch portion positioned above and below the piezoelectric portion to transmit vibration to the piezoelectric portion, and including an adhesive surface attachable to the user's skin;
An electrode part having one end connected to the piezoelectric part and adjacent to the patch part to transmit an electric signal generated from the piezoelectric part; And
Receiving the electrical signal to detect at least one of a heart rate signal or a respiration signal, receiving an electrical signal from the electrode unit and another electrode unit to detect at least one of a heart rate signal or a respiration signal, and a plurality of detected heart rate signals Comprising a control unit for compensating the heart rate signal or the breathing signal by comparing the breathing signal, patch type monitoring device.
The method of claim 1, wherein the electrode unit,
A first upper electrode part positioned above the piezoelectric part;
A second upper electrode part positioned above the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a different path from the first upper electrode part;
A first lower electrode part positioned below the piezoelectric part; And
And a second lower electrode part positioned below the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a path different from that of the first lower electrode part.
The method of claim 2, wherein the control unit,
An upper correction signal is calculated from the electric signal transmitted from the first upper electrode part and the second upper electrode part,
A patch type monitoring device for calculating a lower correction signal from the electric signal transmitted from the first lower electrode part and the second lower electrode part.
The method of claim 2, wherein the control unit,
Generating a first detection signal by detecting at least one of the heartbeat signal or the breathing signal from the electrical signal transmitted through the first upper electrode part and the first lower electrode part,
The heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the second upper electrode part and the second lower electrode part Generating a second detection signal by detecting at least one of,
The heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the first upper electrode part and the second lower electrode part Generating a third detection signal by detecting at least one of,
The heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the second upper electrode part and the first lower electrode part Generating a fourth detection signal by detecting at least one of,
A patch type monitoring device for calculating an average value of the first detection signal, the second detection signal, the third detection signal, and the fourth detection signal.
The method of claim 2, wherein the control unit,
Generating a fifth detection signal by detecting at least one of the heartbeat signal or the respiration signal from the electrical signal transmitted through the first upper electrode part and the first lower electrode part,
A patch type for generating a sixth detection signal by detecting at least one of the heartbeat signal or the respiration signal different from the fifth detection signal from the electric signal transmitted through the second upper electrode part and the second lower electrode part Monitoring device.
The method of claim 5, wherein the control unit,
Generating a seventh detection signal by detecting at least one of the heartbeat signal or the respiration signal that is the same as the fifth detection signal from the electrical signal transmitted through the first upper electrode part and the second lower electrode part,
Patch type for generating an eighth detection signal by detecting at least one of the heartbeat signal or the respiration signal identical to the sixth detection signal from the electrical signal transmitted through the second upper electrode part and the first lower electrode part Monitoring device.
The method of claim 6, wherein the control unit,
Generating a first correction signal from the fifth detection signal and the seventh detection signal,
A patch type monitoring device that generates a second correction signal from the sixth detection signal and the eighth detection signal.
The method of claim 1, wherein the control unit,
Receiving the electric signal from the piezoelectric unit,
Separating the electrical signal into different frequency bands,
A patch type monitoring device for detecting at least one of the heartbeat signal or the respiration signal by analyzing the electrical signal divided into the frequency band.
The method of claim 1, wherein the patch unit,
An upper patch part positioned above the piezoelectric part; And
And a lower patch part positioned under the piezoelectric part,
The upper patch part is coupled to the lower patch part and is configured to cover at least one of the piezoelectric part, the patch part, the electrode part, and the control part.
Attaching a device for bonding the adhesive surface to the user's skin;
A piezoelectric detection step of detecting the vibration generated from the outside by the piezoelectric unit from the adhesive surface and generating an electric signal from the vibration;
An electric signal transmission step of transferring the electric signal along an electrode portion electrically connected to the piezoelectric unit; And
Receiving the electrical signal to detect at least one of a heart rate signal or a respiration signal, and by receiving an electrical signal from the electrode unit and another electrode unit receiving the electrical signal to detect at least one of a heart rate signal or a respiration signal, and detect Comprising a heart rate and respiration detection step of compensating the heart rate signal or the respiration signal by comparing the plurality of heart rate signals or respiration signals.
The method of claim 10, wherein the step of detecting the heart rate and respiration,
A first upper electrode part positioned above the piezoelectric part;
A second upper electrode part positioned above the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a different path from the first upper electrode part;
A first lower electrode part positioned below the piezoelectric part; And
And a second lower electrode part positioned under the piezoelectric part and transmitting the electric signal generated from the piezoelectric part through a path different from that of the first lower electrode part.
The method of claim 11, wherein the step of detecting the heart rate and respiration,
An upper correction signal is calculated from the electric signal transmitted from the first upper electrode part and the second upper electrode part,
A patch type monitoring method for calculating a lower correction signal from the electric signal transmitted from the first lower electrode part and the second lower electrode part.
The method of claim 11, wherein the step of detecting the heart rate and respiration,
Generating a first detection signal by detecting at least one of the heartbeat signal or the breathing signal from the electrical signal transmitted through the first upper electrode part and the first lower electrode part,
The heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the second upper electrode part and the second lower electrode part Generating a second detection signal by detecting at least one of,
The heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the first upper electrode part and the second lower electrode part Generating a third detection signal by detecting at least one of,
The heart rate signal or the breathing signal identical to the first detection signal detected from the first upper electrode part and the first lower electrode part from the electric signal transmitted through the second upper electrode part and the first lower electrode part Generating a fourth detection signal by detecting at least one of,
Calculating an average value of the first detection signal, the second detection signal, the third detection signal, and the fourth detection signal.
The method of claim 11, wherein the step of detecting the heart rate and respiration,
Generating a fifth detection signal by detecting at least one of the heartbeat signal or the respiration signal from the electrical signal transmitted through the first upper electrode part and the first lower electrode part,
A patch type for generating a sixth detection signal by detecting at least one of the heartbeat signal or the respiration signal different from the fifth detection signal from the electric signal transmitted through the second upper electrode part and the second lower electrode part Monitoring method.
The method of claim 14, wherein the step of detecting the heart rate and respiration,
Generating a seventh detection signal by detecting at least one of the heartbeat signal or the respiration signal that is the same as the fifth detection signal from the electrical signal transmitted through the first upper electrode part and the second lower electrode part,
Generate an eighth detection signal by detecting at least one of the heartbeat signal or the respiration signal identical to the sixth detection signal from the electrical signal transmitted through the second upper electrode part and the first lower electrode part,
Generating a first correction signal from the fifth detection signal and the seventh detection signal,
Generating a second correction signal from the sixth detection signal and the eighth detection signal, patch type monitoring method.

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