KR20150065123A - Apparatus for measuring bio-signal of hybrid type - Google Patents

Abstract

The present invention relates to an apparatus for measuring a bio-signal of hybrid type. The apparatus for measuring a bio-signal of hybrid type includes a main body which includes a mounting groove which has a sting shape and is formed in a center part, a pair of conductive electrodes which is separated by the mounting grooves to face each other, and touches the skin of a user, and a pair of first connection parts which is located in the lower part of the mounting groove and is connected to the first connection parts, respectively, and a unit for measuring a bio signal which has a pair of second connection parts which is installed to the mounting groove, and corresponds to the connection parts to be detachable from the connection parts, respectively. Thereby, the unit for measuring the bio signal of the apparatus for measuring a bio-signal of hybrid type has a detachable structure. Because apparatus for measuring a bio-signal of hybrid type can be used with a bel shape or patch shape according to the need of a user, the convenience and satisfaction of a user is improved.

Description

[0001] APPARATUS FOR MEASURING BIO-SIGNAL OF HYBRID TYPE [0002]

The present invention relates to a hybrid bio-signal measurement apparatus.

Recently, healthcare products that can measure vital signs have been attracting much attention because of increasing interest in health.

In particular, patients with diseases such as heart disease, hypertension, and diabetes need to visit their clinic and receive medical treatment. In addition, it is necessary to continuously monitor their condition in daily life, to measure the condition of the user in real time, In order to do this, the user should be able to wear the product at all times without feeling uncomfortable in daily life.

Therefore, a health care product that continuously measures a patient's condition should be manufactured in a light and portable form. In order to meet these criteria, a patch type bio-signal measuring device has been developed.

However, in the conventional bio-signal measuring apparatus, most of the bio-signal measuring apparatus is in the form of a patch that touches the user's skin. Therefore, when the bio-signal measuring apparatus is used, when a motion such as walking or exercise occurs, The user's discomfort is increased because the user is restrained from moving.

Korean Patent Publication No. 10-2009-0008786 (published on January 22, 2009, inventor: Hwang Jin Sang et al. 2)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art.

A hybrid bio-signal measuring device according to one aspect of the present invention includes a mounting groove formed at the center of a string, a pair of conductive electrodes positioned facing each other with the mounting groove therebetween, And a pair of first connection portions located below the mounting grooves and connected to the pair of conductive electrodes, respectively. The first and second connection portions are seated in the mounting groove and are positioned to correspond to the pair of first connection portions, respectively And a pair of second connection portions detachably coupled to the pair of first connection portions, respectively.

The pair of first connection portions may be a plurality of buttons, and the pair of second connection portions may be a barb.

Wherein the main body further includes a pair of connection holes formed at both ends of the main body, wherein the main body includes a coupling portion detachably inserted into the pair of coupling holes, a coupling hole connected to the coupling portion, And a detachable unit having a fastening portion having a fastening portion.

Wherein the bio-signal unit is connected to the pair of conductive electrodes and uses an output signal from the pair of conductive electrodes to determine whether the hybrid bio-signal measuring device in use is in a patch form or a belt form A signal processing unit connected to the operation type determination unit and configured to remove a noise component of the biological signal output from the operation type determination unit and a control unit to determine biometric information using the biological signal output from the signal processing unit It is good to do.

Wherein the signal processing unit includes a first signal processor for processing the bio-signal output from the operation type determination unit when the hybrid bio-signal measurement device in use is in the form of a belt, and a second signal processor for processing the bio- And a second signal processor for processing the biological signal output from the operation type determination unit.

The first and second signal processors each include a bandpass filter and the range of the cutoff frequency of the band pass filter of the first signal processor may be narrower than the cutoff frequency range of the band pass filter of the second signal processor .

The controller may determine the pulse number using the bio-signal output from the first signal processor, and determine the electrocardiogram signal waveform using the bio-signal output from the second signal processor.

According to this aspect, the bio-signal measuring unit of the hybrid bio-signal measuring device has a detachable structure, and the hybrid bio-signal measuring device is used in a belt form or in a patch form according to the user's need.

Therefore, since the hybrid bio-signal measurement device is used in a form desired by the user, convenience and satisfaction of the user is increased.

When the hybrid bio-signal measuring device is used in the form of a belt, the user installs a hybrid bio-signal measuring device on his or her body and normally performs daily activities such as exercise, thereby further enhancing the convenience of the user. So that there is no danger that the bio-signal measurement unit will fall off the user's body during bio-signal measurement.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a hiveed bio-signal measuring apparatus according to an embodiment of the present invention; FIG.
2 is an exploded perspective view of the hivbid bio-signal measuring device shown in Fig.
Fig. 3 is a plan view of the belt body in which the bio-signal measuring unit is removed in the hibited bio-signal measuring apparatus shown in Fig. 1. Fig.
FIG. 4 is a bottom view of the hividate bio-signal measuring device shown in FIG. 1. FIG.
5 is an exploded perspective view of the biological signal measuring unit of the hiveed bio-signal measuring device shown in Fig.
6 is a bottom view of the bio-signal measurement unit shown in Fig.
FIG. 7 is a block diagram of a bio-signal measurement unit of the hiveed bio-signal measurement apparatus according to an embodiment of the present invention.
FIG. 8 is a graph showing the relationship between an original bio-signal obtained when a hibited bio-signal measurement apparatus according to an embodiment of the present invention is used in a belt form and a patch form, and a noise signal obtained by removing a noise component of a bio- (A) shows a case in which a hibited bio signal measuring apparatus is used in a belt form, and (b) shows a case in which a hibited bio signal measuring apparatus is used in a patch form.
FIG. 9 is a flowchart illustrating an operation of a control unit of the hividate bio-signal measurement apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Hereinafter, a hybrid bio-signal measuring apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 to 5, an apparatus for measuring a hybrid bio-signal according to an embodiment of the present invention includes a belt-type body (hereinafter referred to as a "body") 10, a bio- A module 20, and a pair of attaching / detaching units 30 detachably mounted at both ends of the body 10.

1 to 4, the main body 10 is formed in the same belt shape as an elongated strip. The main body 10 has a mounting groove 11 in which a living body signal measuring unit 20 is mounted, And a pair of connection holes 12 in which the attaching / detaching unit 30 is mounted at both ends.

The mounting groove 11 has an elliptical planar shape like the living body signal measuring unit 20 because it is a place where the living body signal measuring unit 20 is inserted and seated, Shape.

In the lower portion of the mounting groove 11, two first connection parts 111 for electrical and physical connection with the living body signal measuring unit 20 are located. In this example, the two first connection portions 111 are made up of a number buttons, which are snap buttons.

The two first connection portions 111 are for coupling the living body signal obtained from the living body to the living body signal measuring unit 20 as well as for coupling with the living body signal measuring unit 20 and are made of a conductive material.

A pair of first connection portions (111) are mounted through the main body (10).

On the inner side surface of the mounting groove 11, a pair of engaging projections 112 for engaging with the living body signal measuring unit 20 are located.

In addition, a plurality of stepped portions exist on the inner side surface of the mounting groove 11 for coupling with the bio-signal measuring unit 20. [

The connection hole 12 is for coupling with the attaching / detaching unit 30. The connection hole 12 is formed through the body 10 and has a substantially triangular planar shape. However, the connection hole 12 may have various shapes.

4, a pair of conductive electrodes, that is, first and second conductive electrodes 131 and 132, which are a plurality of living body signal sensors that collect living body signals in contact with the skin of the user, And extends along the extension direction of the main body 10 at positions facing each other with respect to the central portion thereof.

The first and second conductive electrodes 131 and 132 are electrically and physically connected to the pair of first connection portions 111 exposed through the body 10 and exposed to the rear, Each of the electrodes 131 and 132 is connected to the rear surface of the adjacent first connection part 111 of the two first connection parts 111.

On the rear surface of the main body 10, protective covers 113 and 114 for stably positioning and protecting the first and second conductive electrodes 131 and 132 and the connection portion 111 are disposed. 4, a part of the first connection part 111 and the first and second conductive electrodes 131 and 132 are covered with the protective covers 113 and 114, (131, 132) are not exposed on the rear surface.

The main body 10 and the protective covers 113 and 114 may be made of rubber, silicone, urethane, or the like. However, in an alternative example, such protective covers 113 and 114 may be omitted.

Further, a part of the attaching / detaching unit 30 is embedded in the back surface of the belt-shaped body 10.

5, the living body signal measuring unit 20 includes a unit body 21 mounted in the mounting groove 11, a plurality of electric and electronic circuits 222 built in the unit body 21 for processing a living body signal, And a lid 23 which is coupled with the unit main body 21 and protects the printed circuit board 22 located in the unit main body 21. At this time, the connector 233 may be a charging terminal for charging operation.

A lower portion of the unit main body 21 is provided with two openings 211 at positions corresponding to the pair of first connection portions 111. Inside the openings 211, The pair of second connection portions 221 are exposed through the opening 211 and connected to the printed circuit board 22 located at the upper portion as described above, And is coupled with the first connection part 111 located at the lower part.

Accordingly, the second connection unit 221 transmits the biometric signal applied from the first connection unit 111 to the printed circuit board 22 which is located on the top of the first connection unit. As such, the second connection part 221 also functions as a signal transmission terminal like the first connection part 111, and is made of a conductive material for this purpose. At this time, the connection between the second connection portion 221 and the printed circuit board 22 is connected using a conductive pin or the like.

In order to stably perform the fastening with the first connection part 111, the pair of second connection parts 221 are made of a snap-button, and the first connection part 111 and the second connection part 221 Are snap-connected or disconnected from each other according to the direction of the applied force.

At this time, since the second connection portion 221 is stably maintained in the state of bonding by bonding with the unit body 21, the state of the second connection portion 221 can be stably maintained even by repeated snap connection and release operations. do.

However, in an alternative example, the second connection portion 221 may be directly attached to the printed circuit board 22 through a soldering operation, May be exposed to the outside of the first connection part (21) and connected to the first connection part (111).

Therefore, when the bio-signal measuring unit 20 is inserted into the mounting groove 11, the bio-signal measurement can be stably performed in the mounting groove 11 without fear of disconnection due to male and female coupling by the first and second connecting portions 111 and 221 The unit 20 is located.

The rim of the unit main body 21 is formed with a rim protruding in the transverse direction. The rim is located above the edge of the mounting groove 11 and the lid 23 is located above the unit main body 21.

A pair of coupling grooves 112 are formed at the outer side surface of the unit main body 21 so as to be inserted into the coupling projections 112 at portions corresponding to the coupling projections 112 of the mounting grooves 11 and to be engaged with the coupling projections 112 212 are located.

Therefore, when the living body signal measurement unit 20 is inserted into the mounting groove 11, the coupling groove 212 is inserted into the coupling projection 112 in the mounting groove 11 so that the living body signal measurement unit 20 is stable As shown in Fig.

Since the pair of second connection portions 221 are electrically connected to the corresponding portion of the printed circuit board 22 as described above, the printed circuit board 22 is electrically connected to the living body Signal to determine and output a user's biological signal such as a pulse or electrocardiogram signal waveform.

The lid 23 is located on the open upper surface of the unit main body 21 and protects the printed circuit board 22 located in the unit main body 21 from the outside.

5, the cover 24 located at the bottom is made of silicone, rubber, urethane or the like, and the unit body 21 is inserted to surround the outer surface of the unit body 21. At this time, since the second connection portion 221 is exposed to the outside, the cover 24 also has the opening 241 at a position corresponding to the opening 211.

The cover 24 separates the bio-signal measuring unit 20 from the main body 10, mounts only the bio-signal measuring unit 20 on the user's body, and measures the bio-signal using the hybrid bio- , It is intended to reduce the discomfort that may occur when the unit main body 21 made of a plastic material comes into direct contact with the skin of the user and to protect the living body measurement unit 20 from an external impact or the like.

Thus, unlike the present example, in an alternative example, the cover 24 may be omitted.

The pair of attaching and detaching units 30 are connected to the engaging part 31 and the engaging part 31 inserted into the connecting hole 12 located at both ends of the main body 10, And a fastening portion 32 having a fastening hole 321 to which a length-adjustable connection cord 40 is inserted and then coupled.

Therefore, when the user measures the living body signal by using the hybrid bio-signal measuring device in the form of a belt after attaching the body 10 to the user's body after attaching the bio-signal measuring unit 20 to the body 10, The coupling unit 31 of the unit 30 is inserted into the coupling hole 12 of the main body 10 to measure the bio-signal after the main body 10 is opened to the user's body, for example, the chest.

On the other hand, if the engaging portion 31 inserted in the connecting hole 12 is pulled out to unlock the belt body 10 worn on the body, the main body 10 and the attaching / detaching unit 30 are easily separated, The body 10 can be worn and removed.

The shape of the connecting hole 12 varies depending on the shape of the connecting portion 31 and the shape of the connecting portion 31 can also have various plan shapes other than the triangle, Can be changed as needed.

Like the cover 24, the main body 10 is a portion directly contacting the user's skin. Therefore, the main body 10 is made of a material capable of reducing the sense of comfort and uncomfortable feeling upon contact. For example, have.

When the hybrid bio-signal measuring device is used in the form of a belt, the bio-signal measuring unit 20 is placed in the mounting groove 11 of the main body 10 and then the first and second connecting parts 111 and 221 are mounted, .

The main body 10 in which the living body signal measuring unit 20 is mounted on a body part (for example, a chest) to measure a living body signal by connecting the connecting strap 40 and the main body 10 using the attaching / detaching unit 30, .

Next, the living body signal measuring unit 20 is operated to acquire the living body signal through the conductive electrodes 131 and 132 in contact with the skin.

On the other hand, when the hybrid bio-signal measuring apparatus is used in the form of a patch, the bio-signal measuring unit 20 is separated from the main body 10, and then the cover 24 is placed on the unit body 21. If necessary, the operation of covering the unit body 21 with the cover 24 is omitted.

Next, after connecting two patch-type electrodes (not shown) attached with means and measuring the vital signs to the second connection part 221 which is a female terminal, two patch-type electrodes are connected to a desired body part And the living body signal measurement unit 20 is operated to acquire a living body signal.

When the hybrid bio-signal measuring device is used in the form of a patch, two patch-type electrodes connected to the second connection part 221 perform the same function as the first and second conductive electrodes 131 and 132, 2 conductive electrodes 131 and 132, respectively.

The operation of the hybrid bio-signal measuring apparatus having such a structure will be described.

First, a block diagram of the hybrid bio-signal measurement unit 20 will be described with reference to FIG. In the block diagram shown in Fig. 7, all the components are mounted on the printed circuit board 22 except for the conductive electrode portion 51. Fig.

7, the bio-signal measurement unit 20 is connected to the operation type determination unit 52 and the operation type determination unit 52 connected to the conductive electrode unit 51, the conductive electrode unit 51 A control unit 54 connected to the conductive electrode unit 51 and the signal processing unit 53 and a data transfer unit 55 and an operation status display unit 56 connected to the control unit 54. The signal processing unit 53, Respectively.

The conductive electrode portion 51 includes the first and second conductive electrodes 131 and 132 already described.

When the first and second conductive electrodes 131 and 132 are attached to the user's skin, one of the first and second conductive electrodes 131 and 132 (e.g., 132) A closed loop is formed by the first and second conductive electrodes 131 and 132 and the first and second connection parts 111 and 221 obtained by the first and second conductive electrodes 131 and 132. [ 20 to the user's body.

Therefore, the analog type biological signals obtained by the first and second conductive electrodes 131 and 132 are input to the control unit 54 of the biological signal measurement unit 20.

The operation type determination unit 52 determines the operation type of the living body signal in the form of a belt by using the states of the living body signals output from the first and second conductive electrodes 131 and 132 and inputted through the first and second connection units 111 and 221 It is determined whether it is in a measured state or in a state of measuring a bio-signal in the form of a patch.

The level of the biological signal measured by the difference between the amount of noise included in the measured biological signal and the electrical resistance value when the biological signal is measured in the form of a belt and when the biological signal is measured in the form of a patch are different from each other Do.

Accordingly, the operation type determination unit 52 determines whether the hybrid bio-signal measurement apparatus is currently used in a belt form or a patch form, using the level difference of the bio-signal.

For example, within the operation mode determination unit 52, ranges of allowable signal levels when a patch type and a belt type are set are set, respectively.

Therefore, the level of the input bio-signal is compared with the range of the allowable signal level that has been set, and the range of the allowable signal level to which the input bio-signal belongs is determined. After determining whether the patch type or the belt type, And outputs a determination signal to the control unit 54. [

However, when the level of the input bio-signal does not belong to any of the two allowance signal level ranges, the operation type determination unit 52 determines that the hybrid bio-signal measurement device is abnormally attached to the skin of the user, At least one of the two conductive electrodes 131 and 132 is determined to be in an abnormal state away from the user's skin and outputs a form determination signal in the corresponding state to the control unit 54. [

The signal processing unit 53 includes a first signal processor 531 for processing bio-signals output from the operation type determining unit 52 when the hybrid bio-signal measuring device in use is in use in a belt form, And a second signal processor 532 for processing the bio-signal output from the shape determination unit 52. [

To this end, the operation type determination unit 52 outputs a biosignal to the first signal processor 531 when it is determined that the determined measurement form of the bio-signal is in the form of a belt, And outputs the biomedical signal.

As described above, since the amounts of noise included in the bio-signals are different between when in the form of a belt and in the form of a patch, the noise processing operations performed in the first and second signal processors 531 and 532 are also different from each other.

The first and second signal processors 531 and 532 include at least one filter and an amplifier. The first and second signal processors 531 and 532 adjust the cut-off frequency range and signal amplification degree of the corresponding filter, .

As described above, when the hybrid bio-signal measuring device is used in the form of a belt to acquire a living body signal, the obtained living body signal contains more noise components than the case of the patch type.

Accordingly, the cutoff frequency range of the filter used in the first signal processor 531 is set to be narrower than the cutoff frequency range of the filter used in the second signal processor 532, and the signal amplification degree of the first signal processor 531 is set to 2 signal processor 531. In this case, In this case, the signal magnitude and the noise level output from the second signal processor 532 become similar to the signal magnitude and the noise level output from the first signal processor 531.

For example, the operation of the signal processing unit 53 will be described in more detail with reference to FIG.

FIG. 8A shows a biological signal processing process when the hybrid bio-signal measuring device is used in the form of a belt, FIG. 8B shows a biological signal processing process when the hybrid bio- It is.

As shown in FIG. 8, the raw bio-signal S _B (t) obtained directly from the user's skin when in the form of a belt includes a raw bio signal S _p (t) ], It is understood that the degree of distortion of the signal is more severe.

The original bio-signals S _B (t) and S _P (t) are input to the corresponding first and second signal processors 531 and 532, respectively, after noise components are removed.

For example, when the first and second signal processors 531 and 532 are provided with band pass filters (BPF _B and BPF _P ) to remove a noise component, as shown in FIG. 8, cut-off frequency range of the band pass filter (BPF _B) used in the processor 531 may be a 1 to 35㎐, that is, is 1㎐ and the maximum frequency (f _BH) is 35㎐ lowest frequency (f _BL), the The cut-off frequency range of the band-pass filter BPF _P used in the signal processor 532 may be 0.1 to 50 Hz, that is, the lowest frequency f _PL may be 0.1 Hz and the highest frequency f _PH may be 50 Hz .

In order to equalize the pulse sizes of the biological signals (for example, electrocardiogram signals) from which noise components are removed by the first and second signal processors 531 and 532, the first and second signal processors 531 and 532 The amplification degree (A _VB , A _VP ) of the band-pass filter is also set to be different from each other.

Therefore, the final biological signals S _FB (t) and S _FP (t)) obtained by the signal processing operations of the first and second signal processors 531 and 532 may be as shown in FIG.

The final biomedical signals S _FB (t) and S _FP (t) shown in FIG. 8 are set by setting the cut-off frequency range of the filters of the first and second signal processors 531 and 532 and the amplification degree of the signal to the same value .

As shown in Figure 8, in the case when using a hybrid bio-signal measurement unit to a patch-type using a hybrid bio-electrical signal measurement unit into a more belt form to obtain a final biological signal, the signal loss compared to the original living body signal [S _B (t)] The accuracy of the measured ECG signal waveform is degraded.

Therefore, the final bio-signal S _FB (t) obtained by using the belt-shaped hybrid bio-signal measuring device can be input to the control unit 54 and used for measuring pulses such as a pulse, and the hybrid bio- The final bio-signal [S _FP (t)] obtained by using the apparatus is input to the control unit 54 and can be used to more accurately observe the electrocardiogram signal waveform.

Instead of removing the noise component contained in the original biological signal by using the analog signal processing, the biological signal can be converted into the digital state and signal processing can be performed using a software digital filter. The digital filter may be implemented in the control unit 54 or may be implemented as a separate signal processing unit.

At this time, the bio-signal that is converted to a digital state, the final biological signal [S _FB (t), S _FP (t)] or the source bio-signal [S _B (t), S _P (t) output from the signal processing section 53 ]. An example of such a digital filter may be a moving average filter (MAF).

Further, in order to set the noise level of the bio-signal obtained in the belt form and the patch form to the same level, the size of the filter window when the belt form is made different from each other, The size of the filter window for the belt-shaped bio-signal is set larger so that more noise can be removed.

In the case of using such a digital filter, the analog type signal processing unit 53 is omitted and the digital signal processing unit MAF is used instead of the signal processing unit 53 as described above, or the signal processing unit 53, Can be used.

Next, the control unit 54 measures biometrics information such as a desired pulse or electrocardiogram signal waveform using the final bio-signal processed by at least one of the analog form and the digital form, (56).

Further, the control unit 54 controls whether or not the biological signal measurement unit 20 is operated by controlling the operation of the other drive unit by using the operation state of the conductive electrode unit 51.

The data transmission unit 55 transmits the biometric information output from the control unit 54 to an external device such as a smart phone or a computer wirelessly or by wire to output the measured biometric information to the outside do.

The operation status display unit 56 is constituted by a liquid crystal display or the like and displays biometric information output from the control unit 54 so that the user can confirm the biometric information.

Next, the operation of the control unit 54 will be described in more detail with reference to FIG.

When power required for the operation of the bio-signal measuring unit 20 is supplied by the operation of the power source device (not shown), the operation of the control unit 54 is started (S10).

Therefore, the control unit 54 reads the signal output from the conductive electrode unit 51 (S11) and measures the resistance value using the signal output from the conductive electrode unit 51 (S12).

Then, the control unit 54 compares the measured resistance value with the set value (S13).

When the first and second conductive electrodes 131 and 132 are brought into contact with the user's skin in order to use the hybrid bio-signal measuring device in the form of a belt or a patch, the path of the living body signal So that the measured resistance value is less than the set value

However, when at least one of the first and second conductive electrodes 131 and 132 is not in contact with the skin of the user, the biological signal does not flow, so that the measured resistance value becomes almost infinite.

Therefore, when the resistance value measured by the signal output from the conductive electrode unit 51 exceeds the set value, the control unit 54 determines that the hybrid bio-signal measurement apparatus is in an unused state, The process goes to step S11.

However, when the measured resistance value is equal to or less than the set value, it is determined that the bio-signal is measured using the hybrid bio-signal measuring device.

Therefore, the control unit 54 reads the shape determination signal output from the operation form determination unit 52 (S14), and determines the operation form of the currently used hybrid bio-signal measurement apparatus.

When the state of the read morpheme judgment signal is judged to be in the form of a belt (S15), the control unit 54 reads out a living body signal subjected to the noise signal processing output from the first signal processor 531, that is, a final living body signal (S16 , And performs the set processing operation using the read signal (S17). Therefore, for example, the controller 54 counts the number of pulses of the biological signal output from the first signal processor 531 to measure the pulse number (S17), and transmits the measured pulse number to the data transfer unit 55 And outputs it to at least one of the display units 56 (S18).

Thus, the user determines whether the current number of pulses is in a normal state.

However, the state of the determined morphological judgment signal is judged to be a patch form (S19), and the control unit 54 reads the final biomedical signal subjected to the noise signal processing outputted from the second signal processor 532 (S20) (S21). ≪ / RTI > Accordingly, for example, the control unit 54 outputs the final biometric signal to the electrocardiogram signal waveform to at least one of the data transfer unit 55 and the operation status display unit 56 (S21).

However, when the shape of the hybrid bio-signal measuring device determined by the morphological determination signal is not a belt shape but a patch shape, the control unit 54 determines that the level of the bio-signal measured by the conductive electrode unit 51 is the permissible signal level Is determined to be in an abnormal state out of the range of Accordingly, the control unit 54 outputs an alarm signal to at least one of the data transfer unit 55 and the operation status display unit 56 (S22).

Due to this, due to the operation of the external device or the operation state display unit 56, the user can attach the at least one of the first and second conductive electrodes 131 and 132 to the skin in an abnormal state at present, And the contact state of the first and second conductive electrodes 131 and 132 is checked so that a normal bio-signal measurement operation is performed.

As described above, the hybrid bio-signal measuring apparatus according to the present embodiment is used in the form of a belt or a patch according to the user's need or purpose, thereby increasing the satisfaction of the user.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: belt body 11: mounting groove
111: first connection part 12: connection hole
131, 132: conductive electrode 20: biological signal measurement module
21: unit body 22: printed circuit board
23: lid 221: second connection part
30: attachment / detachment unit 31:
32: fastening part 321: fastening hole
51: conductive electrode part 52: operating mode judging part
53: signal processor 531: first signal processor
532: second signal processor 54:
55: Data transfer unit 56: Operation status display unit

Claims (7)

A pair of conductive electrodes which are in the form of a string and which are formed in the middle portion and which are in contact with each other with the mounting grooves therebetween and are in contact with the skin of the user, And a pair of first connection portions connected to the first connection portions, respectively, and
And a pair of second connection portions that are seated in the mounting groove and are positioned so as to correspond to the pair of first connection portions and detachably coupled to the pair of first connection portions, respectively,
And a second bio-signal measuring device. The method of claim 1,
Wherein the pair of first connection portions is a button and the pair of second connection portions is a barrel. The method of claim 1,
The main body further includes a pair of connection holes formed at both ends,
And a coupling portion having a coupling portion detachably inserted into the pair of coupling holes, and a coupling portion connected to the coupling portion and having a coupling hole into which the coupling cord is inserted,
Further comprising: a bio-signal measuring device for measuring the bio-signal. The method of claim 1,
Wherein the bio-signal unit is connected to the pair of conductive electrodes and uses an output signal from the pair of conductive electrodes to determine whether the hybrid bio-signal measuring device in use is in a patch form or a belt form part,
A signal processing unit connected to the operation type determination unit and configured to remove a noise component of the biological signal output from the operation type determination unit,
And a controller for determining the biometric information using the biometric signal outputted from the signal processing unit
And a second bio-signal measuring device. 5. The method of claim 4,
Wherein the signal processing unit includes a first signal processor for processing the bio-signal output from the operation type determination unit when the hybrid bio-signal measurement device in use is in the form of a belt, and a second signal processor for processing the bio- And a second signal processor for processing the bio-signal output from the operation type determination unit. The method of claim 5,
Wherein the first and second signal processors each include a band pass filter and the range of the cutoff frequency of the band pass filter of the first signal processor is narrower than the cutoff frequency range of the band pass filter of the second signal processor. Signal measuring device. The method of claim 5,
Wherein the controller determines the pulse number using the bio-signal output from the first signal processor,
And judges an electrocardiogram signal waveform by using the bio-signal output from the second signal processor.

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