KR101210659B1 - A pulse oximeter improving alarm correctness - Google Patents

Abstract

The present invention relates to an oxygen saturation measuring device for improving the accuracy of the oxygen saturation alarm, and more specifically, (1) a light emitting module for irradiating at least two or more lights having different wavelengths to a specific part of the body; (2) a light detection module for receiving light passing through a specific part of the body and detecting the intensity of the received light as an electric signal; (3) an oxygen saturation measurement module configured to derive and quantify oxygen saturation from the electrical signal detected by the optical detection module; And (4) an alarm module for generating an alarm when the quantified oxygen saturation falls below a preset threshold.
According to the oxygen saturation measurement device proposed in the present invention, which improves the accuracy of the alarm, the area calculation unit for calculating the area according to time of the portion where the oxygen saturation has fallen below the first threshold value, and the area calculation unit By including an alarm module having an alarm generating unit for generating an alarm when the calculated area is greater than or equal to a preset second threshold value, it is possible to reduce an erroneous alarm given even though it is not an emergency and to accurately determine an emergency situation and generate an alarm. .

Description

A PULSE OXIMETER IMPROVING ALARM CORRECTNESS

The present invention relates to an oxygen saturation measuring device, and more particularly, to an oxygen saturation measuring device with improved accuracy of an oxygen saturation alarm.

Oxygen saturation measuring device among various monitoring devices to reduce the mortality rate of an emergency patient occurs by measuring non-invasive blood oxygen saturation (SpO) by measuring light absorption by wavelength due to pulsating component of arterial blood. ₂ ) More specifically, light having at least two wavelengths different from each other is irradiated to a specific body part such as a fingertip or earlobe, and light received through the specific body part is absorbed by oxygenated hemoglobin and unoxygenated hemoglobin. Pulse Oximeters are measured according to the difference in the intensity of the transmitted light due to the difference. Patients of the oxygen saturation measuring device are patients with difficulty in breathing, consciousness disorder, shock, heart failure, gas poisoning, and asphyxiation.

1 is a diagram showing an oxygen saturation graph that can be obtained from an oxygen saturation measuring device. In the general oxygen saturation measuring apparatus, as shown in FIG. 1, when the oxygen saturation falls below a predetermined threshold value, an alarm is generated through an alarm to allow a clinician to grasp a situation. However, there is a problem that the fatigue of the medical staff and the patient increases when a false alarm is given even when the oxygen saturation falls below a predetermined threshold as shown in FIG.

In addition, if the alarm is controlled using a range of preset thresholds to reduce false alarms or by using a cumulative time when oxygen saturation falls below a preset threshold, the false alarm can be reduced, but the clinician can identify the actual situation. The problem is that there is still a possibility that it cannot.

The present invention has been proposed to solve the above problems of the conventionally proposed methods, the area calculation unit for calculating the area according to the time of the portion where the oxygen saturation falls below a predetermined threshold value, and the area calculation unit By including an alarm module having an alarm generating unit for generating an alarm when a predetermined area is equal to or more than a predetermined threshold area value, an alarm module capable of generating an alarm by accurately determining an emergency situation while reducing false alarms that are not given an emergency situation. It is an object of the present invention to provide an oxygen saturation measuring device with improved accuracy.

Oxygen saturation measurement device according to the characteristics of the present invention for achieving the above object, the accuracy of the oxygen saturation alarm is improved,

(1) a light emitting module for irradiating at least two or more lights having different wavelengths to a specific part of the body;

(2) a light detection module for receiving light passing through a specific part of the body and detecting the intensity of the received light as an electric signal;

(3) an oxygen saturation measurement module configured to derive and quantify oxygen saturation from the electrical signal detected by the optical detection module; And

(4) It is characterized in that it comprises an alarm module for generating an alarm when the numerical oxygen saturation degree falls below a predetermined threshold value.

Preferably, the oxygen saturation alarm module,

An area calculator configured to calculate an area according to time of a portion of the oxygen saturation derived from the oxygen saturation measurement module having fallen below a preset threshold;

It may be configured to include an alarm generator for generating an alarm when the area calculated by the area calculator is equal to or greater than a predetermined threshold area value.

More preferably, the area calculator,

By integrating the difference between the oxygen saturation degree derived from the oxygen saturation measurement module and a predetermined threshold with respect to time, the area according to time of the portion where the oxygen saturation degree derived from the oxygen saturation degree measurement module falls below a preset threshold value is obtained. Can be calculated.

More preferably, the alarm generating unit,

An alarm may be generated when the sum of the respective area values within a preset time is equal to or larger than the second predetermined threshold area value.

More preferably, the alarm generating unit,

When the part falling below the preset threshold returns to the above threshold, the set time is set, and when the preset time interval elapses from the set time, the reset time is set.

If a portion that falls below the preset threshold occurs within the preset time interval, the generated area value may be weighted.

More preferably, the alarm generating unit,

In the case of generating an alarm, a wired or wireless network may be used to communicate the alarm to an external medical institution system.

More preferably, the alarm generating unit,

It can monitor the power supply status of the main power supply and generate an alarm in case of power failure.

Preferably, the light emitting module,

It may be configured as one of a light emitting diode or a laser diode.

Preferably, the optical detection module,

A light detector which receives the light transmitted through the specific part of the body and converts the light into a current; And

It may be configured to include a current-voltage converter for converting the current generated in the light detector to a voltage.

Preferably, the oxygen saturation measurement module,

A ratio calculator for calculating an oxygen saturation degree using an oxygen saturation measurement algorithm from the electrical signal detected by the optical detection module; And

And a lookup table corrector for correcting the oxygen saturation calculated by the ratio calculator using a lookup table for correcting oxygen saturation.

According to the oxygen saturation measurement device proposed in the present invention, which improves the accuracy of the alarm, the area calculation unit for calculating the area according to time of the portion where the oxygen saturation has fallen below the first threshold value, and the area calculation unit By including an alarm module having an alarm generating unit for generating an alarm when the calculated area is greater than or equal to a preset second threshold value, it is possible to reduce an erroneous alarm given even though it is not an emergency and to accurately determine an emergency situation and generate an alarm. .

1 is a graph illustrating an oxygen saturation graph showing various oxygen saturation levels that can be measured by an oxygen saturation measuring device with time.
Figure 2 is a block diagram of an oxygen saturation measuring device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention.
Figure 3 is a view showing the detailed configuration of the optical detection module 200 of the oxygen saturation measuring device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention.
Figure 4 is a view showing the detailed configuration of the oxygen saturation measurement module 300 of the oxygen saturation measurement device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention.
5 is a view showing a detailed configuration of the alarm module 400 of the oxygen saturation measurement device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention.

Hereinafter, preferred 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. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The same or similar reference numerals are used throughout the drawings for portions having similar functions and functions.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

2 is a block diagram of an oxygen saturation measuring device for improving the accuracy of the oxygen saturation alarm according to an embodiment of the present invention. Oxygen saturation measurement device to improve the accuracy of the oxygen saturation alarm, as shown in Figure 2, the light emitting module 100 for irradiating at least two or more lights having a different wavelength to a specific part of the body, a specific part of the body An oxygen saturation measurement module for receiving the light passing through the light and detecting the intensity of the received light as an electric signal, and deriving and quantifying the oxygen saturation from the electric signal detected by the light detection module 200 ( 300, and an alarm module 400 for generating an alarm when the quantified oxygen saturation degree falls below a predetermined threshold value.

The light emitting module 100 is a component that irradiates at least two or more lights having different wavelengths to a specific part of the body, and may use a light emitting diode or a laser diode as light emitting means. At this time, since the error may occur due to vibration in a specific part of the body that can be irradiated with light, it may include a finger, wrist, ankle, forehead, etc. with less shaking. When the number of lights having different wavelengths is two or more, the number of light emitting means constituting the light emitting module 100 may also be two or more.

The light detection module 200 is a component that receives the light transmitted through a specific part of the body, and detects the intensity of the received light as an electric signal. 3 is a view showing a detailed configuration of the optical detection module 200 of the oxygen saturation measuring device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention. As shown in FIG. 3, the optical detection module 200 according to the exemplary embodiment of the present invention may include the optical detection unit 210 and the current-voltage conversion unit 220. The light detector 210 is a component that receives light having different wavelengths transmitted through a specific part of the body and converts the light into a current signal, and may be implemented in the form of a diode type photodetector or a photoconductor photodetector. have. The current-voltage converter 220 is a component that converts a current generated by the light detector 210 into a voltage. The reason why the current is converted into a voltage using the current-voltage converter 220 is that the oxygen saturation can be measured more accurately by converting the current into a voltage which is less affected by external noise.

The oxygen saturation measurement module 300 is a component that derives and digitizes the oxygen saturation from the electrical signal detected by the light detection module 200. 4 is a view showing the detailed configuration of the oxygen saturation measurement module 300 of the oxygen saturation measurement device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention. As shown in FIG. 4, the oxygen saturation measurement module 300 according to an embodiment of the present invention may include a ratio calculator 310 and a lookup table corrector 320. The ratio calculator 310 is a component that calculates an approximate oxygen saturation degree using an oxygen saturation measurement algorithm from the electrical signal detected by the light detection module 200, and a known oxygen saturation measurement algorithm such as Beer-Lambert Law. Can be used. The lookup table corrector 320 is a component that corrects the oxygen saturation calculated by the ratio calculator 310 using the oxygen saturation correction lookup table.

The alarm module 400 is an element that generates an alarm when the oxygen saturation value quantified by the oxygen saturation measurement module 300 falls below a preset threshold. The alarm module 400 of the oxygen saturation measuring device which improves the accuracy of the oxygen saturation warning proposed by the present invention immediately alerts the user when the oxygen saturation derived from the oxygen saturation measuring module 300 falls below a preset threshold. Rather than generating, the area of the oxygen saturation derived from the oxygen saturation measurement module 300 is calculated according to the time of the portion where the oxygen saturation degree falls below a predetermined threshold value, and an alarm is generated only when the calculated area is greater than or equal to the preset threshold area value. . This method is clearly distinguished from the related art in which an alarm is generated when the derived oxygen saturation counts the time of the portion where the oxygen saturation degree falls below the preset threshold value and generates an alarm when the counted time is equal to or greater than the preset threshold time value. Comparison between the device proposed by the present invention and existing devices will be described in more detail later with reference to FIG. 1.

5 is a view showing a detailed configuration of the alarm module 400 of the oxygen saturation measurement device to improve the accuracy of the oxygen saturation alarm according to an embodiment of the present invention. As shown in FIG. 5, the alarm module 400 according to an embodiment of the present invention may include an area calculator 410 and an alarm generator 420.

The area calculator 410 is a component that calculates an area according to time of a portion in which the oxygen saturation derived from the oxygen saturation measurement module 300 falls below a preset threshold. For example, the area calculator 410 integrates the difference between the oxygen saturation degree derived from the oxygen saturation measurement module 300 and a predetermined threshold with respect to time, thereby deriving the oxygen derived from the oxygen saturation measurement module 300. The area over time of the portion where the saturation falls below a preset threshold may be calculated. Referring again to FIG. 1, the area calculated by the area calculator 410 is the area of the portion indicated by hatched lines in the graph.

The alarm generator 420 is a component that generates an alarm when the area calculated by the area calculator 410 is equal to or larger than a preset threshold area value. That is, the alarm generating unit 420 is a component that determines that the dangerous situation when the area calculated by the area calculating unit 410 is greater than or equal to a preset threshold area value and generates an alarm to inform that the dangerous situation. According to an embodiment, not only the area calculated by the area calculator 410 is equal to or greater than the preset threshold area value, but the preset time although the area calculated by the area calculator 410 is not greater than or equal to the preset threshold area value. An alarm can be generated even if the sum of the respective area values calculated therein is equal to or larger than the second predetermined threshold area value. That is, even if the calculated area is smaller than the critical area value, even if the sum of the area values calculated within a predetermined time is equal to or greater than another second critical area value, it may be configured to generate an alarm by judging as a dangerous situation.

Further, according to the embodiment, the set time is set when the part falling below the preset threshold returns above the threshold, and the reset time when the preset time interval elapses from the set set time. ), But if a portion that falls below a preset threshold within the time interval occurs, the generated area value may be weighted. An alarm can be generated even if the sum of the calculated area values is given a weight and is equal to or larger than a second predetermined threshold area value. That is, since each calculated area value is small but the frequency of oxygen saturation falls below a preset threshold may be a dangerous state, the present invention sets a time interval so that an alarm may be generated by judging as a dangerous situation even in this case. You can calculate the area value by giving a weight.

In addition, when generating an alarm, the alarm generating unit 420 may transmit an alarm fact to an external medical institution system using a wired or wireless communication network. When the oxygen saturation measuring device is used in a protective institution or at home, not in a medical institution, the alarm generator 530 simultaneously transmits an alarm to an external medical institution system using a wired / wireless communication network to generate an alarm, thereby providing an emergency to the patient. You can cope quickly.

In addition, the alarm generation unit 420 may monitor the power supply state of the main power supply and generate an alarm when the power failure occurs. If the oxygen saturation measuring device is not in good condition due to a power outage, it may not be alarmed and may be fatal to emergency patients. Can be.

Next, referring to FIG. 1 again, the performance of the oxygen saturation measuring device which improves the accuracy of the oxygen saturation alarm according to an embodiment of the present invention will be compared with the conventional oxygen saturation measuring device. FIG. 1 is a diagram illustrating an oxygen saturation graph in which various oxygen saturations that can be measured by an oxygen saturation measuring device are displayed over time.

First, a in FIG. 1 is a case where the oxygen saturation degree is insignificantly dropped below a preset threshold. In this case, the oxygen saturation level has briefly dropped below the threshold value and recovered to a safe state, and thus it may be determined that the oxygen saturation level is not a real risk situation. In the conventional conventional oxygen saturation measuring device that immediately generates an alarm when the oxygen saturation falls below the threshold value, an alarm is generated in the state as shown in FIG. 1A. As a result, the medical staff and the patient increase fatigue due to unnecessary risk situations. can do. On the other hand, in the oxygen saturation measuring apparatus proposed by the present invention, the area according to the time (area hatched in a in FIG. 1) of the portion where the oxygen saturation falls below the preset threshold is less than the preset threshold area value. It is very likely to avoid unnecessary alarms. Of course, depending on the state of the patient, the threshold area value may be set low so as to generate an alarm even in the case of a of FIG. 1.

Next, in FIG. 1B, the time when the oxygen saturation degree falls below a preset threshold is short, but the difference is large. In this case, the time when the oxygen saturation is lower than the threshold is short, but the difference between the measured oxygen saturation and the threshold is large, so it can be determined as a dangerous situation. In the case of a conventional conventional oxygen saturation measuring device that generates an alarm immediately when the oxygen saturation falls below a threshold value, an alarm is generated in the state as shown in FIG. However, in the case of another conventional oxygen saturation measuring device that generates an alarm by using a cumulative time when the oxygen saturation falls below a threshold value, there is a high possibility that the alarm is not generated because the cumulative time is short. In contrast, in the oxygen saturation measuring apparatus proposed by the present invention, an area according to time of the portion where the oxygen saturation falls below a preset threshold value (area hatched in b of FIG. 1) is greater than or equal to a preset threshold area value. This is likely to trigger an alert as appropriate.

In FIG. 1C, the time when the oxygen saturation is lower than the preset threshold is long, but the difference is very small. In this case, although the time when the oxygen saturation is lower than the threshold is long, the difference between the measured oxygen saturation and the threshold is very small, and thus it may be determined that it is not a dangerous situation. In the case of a conventional conventional oxygen saturation measuring device that immediately generates an alarm when the oxygen saturation falls below a threshold value, an unnecessary alarm is generated in the state as shown in FIG. In addition, in the case of another conventional oxygen saturation measuring device that generates an alarm by using a cumulative time when the oxygen saturation falls below a threshold value, the cumulative time is likely to be greater than or equal to a threshold time value, thereby generating an unnecessary alarm. On the other hand, in the oxygen saturation measuring apparatus proposed by the present invention, the area according to the time (area hatched in c of FIG. 1) of the portion where the oxygen saturation falls below the preset threshold is less than the preset threshold area value. It is very likely to avoid unnecessary alarms.

Finally, d in FIG. 1 is a case where the oxygen saturation falls below the preset threshold and then recovers above the threshold again in a short time. In this case, when the oxygen saturation falls below the preset threshold and then recovers above the threshold again, the time when the oxygen saturation falls below the threshold is relatively short and the difference between the measured oxygen saturation and the threshold is different. As it is not large, it can be judged that it is not a dangerous situation. However, it can be judged as a dangerous situation that such a situation is repeated many times in a short time. In the case of a conventional conventional oxygen saturation measuring device that generates an alarm immediately when the oxygen saturation falls below a threshold value, the alarm is generated in the state as shown in FIG. However, since the alarm is repeatedly generated several times in a short time, a patient or medical staff may be tired. In addition, in the case of another conventional oxygen saturation measuring device that generates an alarm using a cumulative time when the oxygen saturation falls below a threshold value, the alarm is not generated because each cumulative time is likely to be below a threshold time value. The result could be a dangerous situation. In contrast, in the oxygen saturation measuring apparatus proposed by the present invention, each area according to the time of the portion where the oxygen saturation falls below a predetermined threshold value (each area shaded in d of FIG. 1) is set to a preset threshold. It is unlikely to generate an alarm because it is likely to be less than the area value. However, according to the exemplary embodiment, the present invention may generate an alarm even when the sum of the area values calculated within the preset time is equal to or greater than the preset second threshold area value. It can trigger an alarm. In particular, since the alarm is generated only when each area is accumulated and exceeds the preset second threshold area value, the situation of repeatedly generating the alarm in a short time in the case of d of FIG. 1 can be avoided. .

Although not shown in the drawings, the oxygen saturation measuring apparatus for improving the accuracy of the oxygen saturation alarm according to an embodiment of the present invention may further include a display unit. The display unit may display a digitized oxygen saturation graph derived from the oxygen saturation measurement module 300 according to time and display the user so that the user can check the liquid crystal display (LCD).

The present invention may be embodied in many other specific forms without departing from the spirit or essential characteristics of the invention.

100: light emitting module 200: light detection module
210: light detector 220: current-voltage converter
300: oxygen saturation measurement module 310: ratio calculation unit
320: lookup table correction unit 400: alarm module
410: area calculating unit 420: alarm generating unit

Claims (10)

Oxygen saturation measuring device to improve the accuracy of oxygen saturation alarm,
(1) a light emitting module for irradiating at least two or more lights having different wavelengths to a specific part of the body;
(2) a light detection module for receiving light passing through a specific part of the body and detecting the intensity of the received light as an electric signal;
(3) an oxygen saturation measurement module configured to derive and quantify oxygen saturation from the electrical signal detected by the optical detection module; And
(4) including an alarm module for generating an alarm when the quantified oxygen saturation falls below a preset threshold,
The oxygen saturation alarm module,
An area calculator configured to calculate an area according to time of a portion of the oxygen saturation derived from the oxygen saturation measurement module having fallen below a preset threshold;
And an alarm generating unit for generating an alarm when the area calculated by the area calculating unit is equal to or larger than a predetermined threshold area value. The oxygen saturation measuring device having improved accuracy of the oxygen saturation alarm.
delete The method of claim 1, wherein the area calculation unit,
By integrating the difference between the oxygen saturation degree derived from the oxygen saturation measurement module and a predetermined threshold with respect to time, the area according to time of the portion where the oxygen saturation degree derived from the oxygen saturation degree measurement module falls below a preset threshold value is obtained. Oxygen saturation measuring device, characterized in that to calculate the accuracy of the oxygen saturation alarm.
The method of claim 1, wherein the alarm generating unit,
And an alarm is generated when the sum of the respective area values calculated by the area calculator within a preset time is equal to or greater than a second predetermined threshold area value, improving the accuracy of the oxygen saturation alarm.
The method of claim 4, wherein the alarm generating unit,
When the part falling below the preset threshold returns to the above threshold, the set time is set, and when the preset time interval elapses from the set time, the reset time is set.
And a weighted portion of the generated area value when a portion falling below the preset threshold occurs within the preset time interval, improving the accuracy of the oxygen saturation alarm.
The method of claim 1, wherein the alarm generating unit,
An oxygen saturation measurement device that improves the accuracy of an oxygen saturation alarm, wherein when the alarm is generated, the alarm is transmitted to an external medical institution system using a wired or wireless communication network.
The method of claim 1, wherein the alarm generating unit,
An oxygen saturation measurement device that improves the accuracy of an oxygen saturation alarm, by monitoring the power supply state of the main power supply and generating an alarm when a power failure occurs.
The method of claim 1, wherein the light emitting module,
Oxygen saturation measuring device, characterized in that the configuration of one of a light emitting diode or a laser diode to improve the accuracy of the oxygen saturation alarm.
The method of claim 1, wherein the optical detection module,
A light detector which receives the light transmitted through the specific part of the body and converts the light into a current; And
And a current-voltage converter for converting a current generated by the light detector into a voltage.
According to claim 1, wherein the oxygen saturation measurement module,
A ratio calculator for calculating an oxygen saturation degree using an oxygen saturation measurement algorithm from the electrical signal detected by the optical detection module; And
And a lookup table corrector for correcting the oxygen saturation calculated by the ratio calculator by using a lookup table for correcting oxygen saturation.

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