KR20230050619A - System and method for monitoring biometrics based on positioning - Google Patents

Abstract

The present invention relates to location-based biometric information monitoring technology and, specifically, relates to a location-based biometric information monitoring system and method that can respond to emergencies by identifying biometric information and location relationships of people in a specific building or area. The location-based biometric information monitoring system according to the present invention comprises: a plurality of wearable devices that measure biometric information, including the body temperature, heart rate, and motion signals of a user, and transmit the biometric information and communication signals in real time through short-distance communication; a plurality of gateways that receive the biometric information and communication signals through short-distance communication from each wearable device, transmit the body temperature in a first cycle and the heart rate in a second cycle through the Internet, and when the body temperature is above a threshold, transmit body temperature in a third cycle and transmit the accumulated heart rates and motion signals; and a monitoring server that stores the biometric information received from each of the gateways over the Internet, analyzes the communication signals, calculates the location of the user, and then calculates biometric information distribution data based on the biometric information and the location of the user.

Description

Location-based biometric information monitoring system and method {System and method for monitoring biometrics based on positioning}

The present invention relates to a location-based biometric information monitoring technology, and more particularly, to a location-based biometric information monitoring system and method capable of coping with emergency situations by identifying biometric information and location relationships of people in a specific building or area.

Due to the spread of COVID-19 infection, human life is threatened all over the world. Quarantine measures to prevent the spread of COVID-19 are being carried out in various places, and quarantine authorities are concentrating on identifying the movement of confirmed patients and blocking the spread of infection through epidemiological investigations.

In the current situation of Corona 19, people are blocked from entering the source by measuring their body temperature before entering a building or a specific area.

However, in this quarantine system, there is no way to deal with the case where a person develops a fever after entering a building or a specific area, and it is very difficult to identify close contacts by identifying the movement of a feverish person or an infected person when they are active in a building or a specific area. there is

In addition, a person with a fever cannot necessarily be considered infected with Corona 19, but there is a problem in that it must be identified and managed as an infected person because of a high body temperature.

Korean Patent Registration No. 10-1818857

The present invention was devised to solve the above problems, and an object of the present invention is to provide a system and method capable of coping with an emergency of the spread of an infectious disease by identifying biometric information and location relationships of people in a specific building or area. is to do

Another object of the present invention is to provide a system and method that can more accurately determine whether or not a febrile person is infected.

To this end, the location-based biometric information monitoring system according to the present invention measures the user's biometric information and transmits the biometric information and communication signals through short-range communication, and a plurality of wearable devices that transmit the biometric information through short-range communication from each wearable device. and a plurality of gateways for receiving communication signals and transmitting them through the Internet, storing biometric information received from each gateway through the Internet, analyzing the communication signals, calculating the user's location, and then calculating the user's location based on the biometric information and the user's location. and a monitoring server that calculates biometric information distribution data.

A location-based biometric information monitoring system according to the present invention includes a wearable device that measures and transmits a user's biometric information through first short-range communication, receives the biometric information from the wearable device through first short-range communication, and includes the biometric information and a communication signal. A portable terminal that transmits via second short-range communication, a gateway that receives biometric information and communication signals from the portable terminal through second short-range communication and transmits the biometric information through the Internet, and the biometric information received from the gateway through the Internet After storing and analyzing the communication signal to calculate the location of the user, a monitoring server for calculating biometric information distribution data based on the biometric information and the user's location is included.

A location-based biometric information monitoring system according to the present invention includes a plurality of wearable devices that measure biometric information including a user's body temperature, heart rate, and motion signals and transmit the biometric information and communication signals in real time through short-range communication, and each of the wearable devices. receives biometric information and communication signals through short-range communication from the Internet, transmits the body temperature in the first cycle and the heart rate in the second cycle through the Internet. a plurality of gateways, and a monitoring server that stores the biometric information received from each gateway through the Internet, analyzes the communication signal, calculates the user's location, and calculates the biometric information distribution data based on the biometric information and the user's location. includes

The location-based biometric information monitoring system according to the present invention includes a plurality of wearable devices and a camera for measuring biometric information including a user's body temperature and heart rate and transmitting the biometric information and communication signals in real time through short-range communication, and a camera. Receives biometric information and communication signals from each wearable device through short-range communication and transmits the body temperature in the first cycle and the heart rate in the second cycle through the Internet. A plurality of gateways that transmit video signals, store the biometric information received from each gateway through the Internet, analyze the communication signal to calculate the user's location, and then calculate the biometric information distribution data based on the biometric information and the user's location Includes a monitoring server that calculates

As described above, the present invention generates biometric information distribution data by periodically measuring biometric information such as body temperature and location of people in a building or a specific area, so that in an emergency situation of infection spread, close contact located in the movement of a person with fever or an infected person It has the effect of quickly and accurately identifying the contact.

In addition, the present invention has the effect of determining whether or not the fever person is infected more accurately by analyzing the heart rate and movement of the fever person in addition to the body temperature.

1 is a diagram showing a schematic configuration of a location-based biometric information monitoring system according to a first embodiment of the present invention.
2 is a diagram showing an internal configuration of a wearable device according to a first embodiment of the present invention.
3 is a diagram showing the configuration of a location-based biometric information monitoring system according to a second embodiment of the present invention.
Figure 4 is a diagram showing the internal configuration of the monitoring server according to an embodiment of the present invention.
5 is a view showing an example of biometric information distribution data for identifying close contacts located in the movement line of an infected person according to an embodiment of the present invention.
6 is a diagram showing an internal configuration of a wearable device according to a third embodiment of the present invention.
7 is a diagram showing an internal configuration of a wearable device according to a fourth embodiment of the present invention.
8 is a flowchart illustrating a process of a gateway according to the present invention;
Figure 9 is a flow chart showing the processing of the monitoring server according to the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. The configuration of the present invention and its operational effects will be clearly understood through the following detailed description.

Prior to the detailed description of the present invention, the same components are denoted by the same reference numerals as much as possible even if they are displayed on different drawings, and detailed descriptions of well-known components may be omitted if it is determined that the gist of the present invention may be obscured. Note that do.

1 shows a schematic configuration of a location-based biometric information monitoring system according to a first embodiment of the present invention.

The location-based biometric information monitoring system according to the present invention may be implemented in a building or a specific area where people gather. Buildings or specific areas where people gather can be schools, offices, hospitals, parks, subway stations, etc.

Referring to FIG. 1 , a location-based biometric information monitoring system according to a first embodiment of the present invention is implemented in a school and is composed of a wearable device 10, a gateway 20, a monitoring server 30, and the like.

Since the location-based biometric information monitoring system according to the first embodiment of the present invention is implemented in schools, the wearable devices 10 are carried by students and teachers. The wearable device 10 may be configured in the form of a band worn on a wrist.

A plurality of gateways 20 are installed at school gates and buildings in the school, and the gateways 20 communicate with the wearable device 10 in a short distance and are connected to the monitoring server 30 through the Internet.

Each gateway 20 receives biometric information and communication signals from the wearable device 20 while performing short-range communication with the wearable device 10 and transmits them to the monitoring server 30 through the Internet. The monitoring server 30 analyzes the communication signal of the wearable device 20 to calculate the location of each wearable device 10 and generates biometric information distribution data based on the biometric information and the location.

2 shows the internal configuration of the wearable device 10 according to the first embodiment of the present invention.

Referring to FIG. 2 , the wearable device 10 includes a temperature sensor 11, a short range communication module 12, a memory 13, a display unit 14, a controller 15, and the like.

A body temperature monitoring program is stored in the memory 13 . The wearable device 10 executes a body temperature monitoring program through the controller 15 to perform a body temperature monitoring operation.

The wearable device 10 periodically measures the user's body temperature through the temperature sensor 11 and transmits the temperature value and communication signal to the gateway 20 through the short range communication module 12 . The short-range communication module 12 is a WiFi module.

Here, the communication signal means a signal including a presence signal output by the wearable device 10 in response to an excitation signal (stimulus) of the gateway 20 and identification information (ID) of the wearable device 10 .

The wearable device 10 may accumulate temperature values through a body temperature monitoring program and set a user's normal state reference temperature based on an average value derived from the accumulated temperature values. The wearable device 10 may output a warning message to the user through the display unit 14 when the measured temperature value is out of a preset normal body temperature range.

The gateway 20 is an access point (AP) for WiFi communication. A plurality of gateways 20 are installed in a building or a specific area. Each gateway 20 performs Wi-Fi communication with the wearable device 10, receives a temperature value and a communication signal (strength of the presence signal and identification information) from the wearable device 10, and transmits it to the monitoring server 30 through the Internet do.

The monitoring server 30 stores the temperature value received from each gateway 20 and analyzes the communication signal to calculate the user's location within a building or a specific area. The monitoring server 30 calculates body temperature information distribution data based on the temperature value and the user's location.

The monitoring server 30 may determine a person located around the user outside the normal body temperature range using the body temperature information distribution data. In addition, when an infected person occurs in a building or a specific area, the monitoring server 30 may classify close contacts located in the movement line of the infected person using body temperature information distribution data.

3 shows the configuration of a location-based biometric information monitoring system according to a second embodiment of the present invention.

The location-based biometric information monitoring system according to the second embodiment of the present invention is different in that a user's portable terminal is added in addition to the wearable device.

Referring to FIG. 3 , the location-based biometric information monitoring system according to the second embodiment of the present invention includes a wearable device 100, a portable terminal 200, a gateway 20, a monitoring server 30, and the like.

The wearable device 100 may be configured in the form of a band worn on a wrist. A temperature sensor 101 and a first short-distance communication module 102 are embedded in the wearable device 10 . The wearable device 100 periodically measures the user's body temperature through the temperature sensor 101 and transmits the temperature value to the portable terminal 200 through the first short-range communication module 102 . The first short-distance communication module 101 is a Bluetooth module.

The portable terminal 200 includes a first short-distance communication module 201, a second short-distance communication module 202, a memory 203, an I/O interface 204, a control unit 205, and the like.

A body temperature monitoring application is stored in the memory 203 . The portable terminal 200 executes a body temperature monitoring application through the controller 25 to receive a temperature value from the wearable device 100 through the first short-range communication module 201, and through the second short-range communication module 202 The temperature value and communication signal are transmitted to the gateway 20. The second short-distance communication module 202 is a WiFi module.

The portable terminal 200 may output a warning message to the user through the I/O interface 204 when the body temperature is out of the normal body temperature range through the monitoring application.

Each gateway 20 performs Wi-Fi communication with the portable terminal 200, receives temperature values and communication signals from the portable terminal 200, and transmits them to the monitoring server 30 through the Internet.

Similar to the first embodiment, the monitoring server 30 stores the temperature value received from each gateway 20 and analyzes the communication signal to calculate the user's location within a building or a specific area. The monitoring server 30 calculates body temperature information distribution data based on the temperature value and the user's location.

The monitoring server 30 may determine a person located around the user outside the normal body temperature range using the body temperature information distribution data. In addition, when an infected person occurs in a building or a specific area, the monitoring server 30 may classify close contacts located in the movement line of the infected person using body temperature information distribution data.

Figure 4 shows the internal configuration of the monitoring server according to an embodiment of the present invention.

Referring to FIG. 4 , the monitoring server 30 includes a database 31, a positioning unit 32, a biometric information distribution data generation unit 33, a classification unit 34, and the like.

The monitoring server 30 receives biometric information and communication signals of each wearable device from each gateway 20 through the Internet and stores them in the database 31 .

The positioning unit 32 of the monitoring server 30 analyzes the communication signals accumulated and stored in the database 31 to calculate the location of the user carrying the wearable device or portable terminal. That is, the positioning unit 32 may calculate location information of a user within a building or a specific area using the strength and identification information of the existence signal included in the communication signal and the location information (coordinate values) of the gateway.

The biometric information distribution data generation unit 33 generates biometric information distribution data using the biometric information of each user accumulated and stored in the database 31 and the location information of each user calculated by the positioning unit 32 .

5 shows an example of biometric information distribution data for identifying close contacts located in the movement line of an infected person according to an embodiment of the present invention.

Referring to FIG. 5 , each point in the biometric information distribution data represents a location of a user in a building or a specific area. Such biometric information distribution data may be generated at regular intervals.

Here, reference numeral 1 denotes a user whose biometric information is measured out of the normal range, and reference numeral 2 denotes a user whose biometric information is measured outside the normal range.

When the biometric information is the body temperature, reference numeral 1 may indicate a person with a fever of, for example, 37.5 degrees or more, and reference numeral 2 may indicate a user with a normal body temperature.

The classification unit 34 may classify a person located within a certain range 3 of the person 1 having abnormal biometric information as a close contact by using the biometric information distribution data. Specifically, by analyzing accumulated biometric information distribution data generated at regular intervals, it is possible to classify a person 2 continuously located within a certain range of the fevered person 1 as a close contact for a predetermined period of time.

6 shows the internal configuration of the wearable device 10 according to the third embodiment of the present invention.

Referring to FIG. 6 , the wearable device 10 includes a temperature sensor 11, a short-range communication module 12, a memory 13, a display unit 14, a controller 15, a heart rate sensor 16, and a motion sensor 17. ), etc.

The memory 13 stores body temperature, heart rate and motion monitoring programs. The wearable device 10 executes a body temperature, heart rate, and motion monitoring program through the controller 15 to perform body temperature, heart rate, and motion monitoring operations.

The wearable device 10 periodically measures the user's body temperature, heart rate, and motion through the temperature sensor 11, heart rate sensor 16, and motion sensor 17, and measures the temperature value and heart rate through the short-range communication module 12. , motion signals and communication signals are transmitted to the gateway 20. The short-range communication module 12 is a WiFi module.

Here, the communication signal means a signal including a presence signal output by the wearable device 10 in response to an excitation signal (stimulus) of the gateway 20 and identification information (ID) of the wearable device 10 .

The wearable device 10 may accumulate temperature values (body temperature) through a body temperature monitoring program and set a user's normal state reference temperature based on an average value derived from the accumulated temperature values. The wearable device 10 may output a warning message to the user through the display unit 14 when the measured temperature value is out of a preset normal body temperature range.

The gateway 20 is an access point (AP) for WiFi communication. A plurality of gateways 20 are installed in a building or a specific area. Each gateway 20 performs Wi-Fi communication with the wearable device 10, and receives temperature values, heart rates, motion signals, and communication signals (strength of the presence signal and identification information) from the wearable device 10, and monitors the server through the Internet. Send to (30).

At this time, the gateway 20 transmits the body temperature in the first cycle, the heart rate in the second cycle, and transmits the body temperature in the third cycle if the body temperature is higher than the threshold value, while transmitting the accumulated heart rate and motion signal to the monitoring server 30.

Whenever the gateway 20 receives biometric information from the wearable device 10, if it is directly transmitted to the monitoring server 30, a load may occur on the monitoring server 30. The biometric information may be transmitted at a period longer than the measurement period of , or stored without transmission, and transmitted to the monitoring server 30 only when an event occurs.

For example, the wearable device 10 may measure a body temperature every 3 minutes, measure a heart rate every 1 hour, measure a motion signal every 10 seconds, and transmit the measured motion signal to the gateway 20 . In this case, the gateway 20 transmits the body temperature every 30 minutes, while the heart rate transmits every hour like the cycle of the wearable device 10 because the cycle is long, and the motion signal can only be accumulated without transmitting. In this way, the body temperature is transmitted longer than the measurement period of the wearable device 10, the heart rate is transmitted at the same period, and motion signals are accumulated. Meanwhile, the accumulated heart rate and motion signals may be transmitted to the monitoring server 30. Here, the accumulated heart rate and motion signals refer to data accumulated for a predetermined period before the point at which a body temperature higher than a threshold value is received.

The monitoring server 30 stores the temperature value received from each gateway 20 and analyzes the communication signal to calculate the user's location within a building or a specific area. The monitoring server 30 calculates body temperature information distribution data based on the temperature value and the user's location.

The monitoring server 30 may determine a person located around the user outside the normal body temperature range using the body temperature information distribution data. In addition, when an infected person occurs in a building or a specific area, the monitoring server 30 may classify close contacts located in the movement line of the infected person using body temperature information distribution data.

In addition, when the monitoring server 30 receives the accumulated heart rate and motion signals from the gateway 20, it can analyze the heart rate and motion signals to determine whether fever of the user (subject) is related to infection.

The monitoring server 30 analyzes the received heart rate, determines that the heart rate rises within the critical range (5 to 30) as a normal state, and analyzes the motion signal when the heart rate rises above the critical range so that the user is in an exercise state. If there is, it can be judged as normal, and if it is not in a transported state, it can be judged as suspected infection (dangerous situation).

7 shows the internal configuration of the wearable device 10 according to the fourth embodiment of the present invention.

Referring to FIG. 7 , the wearable device 10 includes a temperature sensor 11, a short-distance communication module 12, a memory 13, a display unit 14, a controller 15, a heart rate sensor 16, and the like. , The gateway 20 is equipped with a camera 22 .

The wearable device 10 periodically measures the body temperature and heart rate of the user through the temperature sensor 11 and the heart rate sensor 16, and transmits the temperature value, heart rate and communication signal through the short-range communication module 12 to the gateway 20. send to

Meanwhile, the gateway 20 uses the camera 22 to capture a surrounding user (subject) and accumulate camera image signals related to the user's movement.

As described above in the third embodiment, the wearable device 10 may measure the body temperature every 3 minutes and measure the heart rate every 1 hour and transmit them to the gateway 20 .

At this time, the gateway 20 may transmit the body temperature every 30 minutes (first cycle) and the heart rate every hour (second cycle). In this way, the body temperature is transmitted longer than the measurement period of the wearable device 10, and the heart rate is transmitted identically to the measurement period of the wearable device 10, and when the body temperature exceeds the threshold, the gateway 20 transmits every 30 minutes. The body temperature may be transmitted every 15 minutes (the third cycle), while the accumulated heart rate and camera image signals may be transmitted to the monitoring server 30 . Here, the accumulated heart rate and camera image signal refer to data accumulated for a predetermined period before the point at which a body temperature higher than a threshold value is received.

Upon receiving the accumulated heart rate and camera image signal from the gateway 20, the monitoring server 30 analyzes the heart rate and camera image signal to determine whether fever of the user (subject) is related to infection.

The monitoring server 30 analyzes the received heart rate, determines that the heart rate rises within a critical range (5 to 30) as a normal state, and analyzes the camera video signal when the heart rate rises above the critical range, so that the user is in an exercise state. If it is in the normal state, it can be judged to be in a normal state, and if it is not in a transport state, it can be judged as a suspected infection (risk situation).

8 shows a processing procedure of a gateway according to the present invention.

Referring to FIG. 8 , the gateway 20 receives biometric information and communication signals from the wearable device 10 (S10). The biometric information includes body temperature and heart rate, and may include a motion signal according to an embodiment.

The gateway 20 checks the body temperature included in the biometric information (S12), and transmits the body temperature in the first cycle and the heart rate in the second cycle if the body temperature is within the threshold (S16).

If the body temperature is higher than the threshold value, the gateway 20 transmits the body temperature in a third cycle (S14). In this case, the transmission period of the heart rate may be constant regardless of a change in body temperature.

Here, the threshold of body temperature may be set by a manager. Normal body temperature can generally change within 0.4 to 0.5 degrees depending on the time of day, temperature, and physical condition. Medically, based on oral temperature, a fever is considered to be 37.2 degrees or higher in the morning and 37.7 degrees or higher in the afternoon or evening. do.

A body temperature threshold that can be regarded as having a fever may be determined in consideration of such a general body temperature change, and body temperature thresholds may be set differently for morning and afternoon hours.

In this way, if the body temperature is confirmed to be higher than the set threshold value, the body temperature is transmitted in the third cycle, while the gateway 20 receives the accumulated heart rate from the wearable device 10 along with the accumulated motion signal or the gateway 20. The acquired and accumulated camera image signals from the provided camera 22 are transmitted to the monitoring server 30 (S18).

Figure 9 shows the processing of the monitoring server according to the present invention.

Referring to FIG. 9, when the monitoring server 30 receives accumulated data (heart rate, motion signal, camera image signal, etc.) from the gateway 20 (S30), it determines whether the subject's fever is related to infection. prepare for analysis.

The monitoring server 30 performs a confirmation operation on external environment data prior to analyzing the cumulative data (S32). That is, the monitoring server 30 is connected to an external server such as the Korea Meteorological Administration and receives information such as weather and temperature from the external server to determine whether external environment data is within a normal range.

Since changes in body temperature caused by sudden weather changes, such as severe cold or heat waves, are not actual fever symptoms of the user, the monitoring server 30 does not analyze the accumulated data if the external environment data is outside the normal range (S36).

However, if the external environment data is in the normal range. The monitoring server 30 analyzes the accumulated data (S34).

When the monitoring server 30 receives the accumulated heart rate and motion signal and/or camera image signal from the gateway 20, the heart rate and motion signal and/or camera image signal are analyzed to determine whether the fever of the user (subject) is related to infection. It can be determined whether there is

The monitoring server 30 analyzes the received heart rate, determines a normal state when the heart rate rises within the critical range (5 to 30), and analyzes the motion signal and/or camera video signal when the heart rate rises above the critical range. Therefore, if the user is in an exercise state, it can be determined as a normal state, and if the user is not in a transport state, it can be determined as a suspected infection (dangerous situation).

In other words, even if the heart rate rises above the critical range, if the user exercises or moves quickly, the change in body temperature and heart rate is not caused by a health problem, so it is judged normal. If there is a change, it can be judged that a health problem has occurred.

The above description is only illustrative of the present invention, and various modifications may be made by those skilled in the art without departing from the technical spirit of the present invention.

Therefore, the embodiments disclosed in the specification of the present invention are not intended to limit the present invention. The scope of the present invention should be construed by the claims below, and all techniques within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Example 1
10: wearable device 11: temperature sensor
12: short-range communication module 13: memory
14: display unit 15: control unit
20: gateway 30: monitoring server
Second embodiment
100: wearable device 101: temperature sensor
102: first short-distance communication module 200: mobile terminal
201: first short-range communication module 202: second short-range communication module
203: memory 204: I/O interface
205: control unit
20: gateway 30: monitoring server
3rd embodiment
10: wearable device 11: temperature sensor
12: short-range communication module 13: memory
14: display unit 15: control unit
16: heart rate sensor 17: motion sensor
20: gateway 30: monitoring server
Example 4
10: wearable device 11: temperature sensor
12: short-range communication module 13: memory
14: display unit 15: control unit
16: heart rate sensor
20: gateway 22: camera
30: monitoring server

Claims (6)

A plurality of wearable devices that measure biometric information including a user's body temperature, heart rate, and motion signals and transmit the biometric information and communication signals in real time through short-range communication;
Receiving biometric information and communication signals through short-range communication from each of the wearable devices, transmitting the body temperature in the first cycle and the heart rate in the second cycle through the Internet, and transmitting the body temperature in the third cycle when the body temperature is higher than the threshold value, and the accumulated heart rate and A plurality of gateways for transmitting motion signals;
Location-based biometric information including a monitoring server that stores the biometric information received through the Internet from each of the gateways, analyzes communication signals, calculates the user's location, and then calculates biometric information distribution data based on the biometric information and the user's location. information monitoring system. According to claim 1,
The monitoring server analyzes the accumulated heart rate and motion signals to determine normal when the heart rate rises above a threshold range and the user is in an exercise state, and when the heart rate rises above a threshold range and the user is not in an exercise state, it is considered dangerous. A location-based biometric information monitoring system characterized in that it is judged by the situation. According to claim 1,
Wherein the gateway comprises a camera and transmits accumulated camera image signals to the monitoring server when the body temperature is higher than a threshold value. A plurality of wearable devices that measure biometric information including a user's body temperature and heart rate and transmit biometric information and communication signals in real time through short-range communication;
It is equipped with a camera, receives biometric information and communication signals from each wearable device through short-range communication, transmits body temperature in the first cycle and heart rate in the second cycle through the Internet, and transmits the body temperature in the third cycle if the body temperature is higher than the threshold value. On the other hand, a plurality of gateways for transmitting the accumulated heart rate and camera image signals;
Location-based biometrics including a monitoring server that stores the biometric information received from each of the gateways through the Internet, analyzes communication signals, calculates the user's location, and then calculates biometric information distribution data based on the biometric information and the user's location. information monitoring system. According to claim 4,
The monitoring server analyzes the accumulated heart rate and the camera image signal to determine normal when the heart rate rises above a threshold range and the user is in an exercise state, and when the heart rate rises above a threshold range and the user is not in an exercise state. A location-based biometric information monitoring system characterized in that it is determined as a dangerous situation. According to claim 2 or 5,
Wherein the monitoring server receives real-time external environment data from the Korea Meteorological Administration server and performs analysis to determine a normal or dangerous situation only when the external environment data falls within a normal range.

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