KR20060008607A - Wireless body temperature measurement system and method thereof - Google Patents

Abstract

A wireless body temperature measurement system and a wireless body temperature measurement method using the same are disclosed. The wireless body temperature measurement system according to the present invention is a sensor for measuring the body temperature of the body in contact with a predetermined part of the body, a comparator for comparing the measured body temperature with a set reference value, and measured when the difference between the body temperature and the reference value is a predetermined value or more And a transmitter terminal having a transmitter for transmitting the body temperature as a radio signal, a receiver for receiving a radio signal transmitted from the transmitter terminal, and a receiver terminal having a display displaying the received radio signal.

Wireless, temperature measurement, bluetooth, alarm, display, sensor

Description

Wireless body temperature measuring system and wireless body temperature measuring method using same {Wireless body temperature measurement system and method

1 is a block diagram schematically showing a wireless body temperature measurement system according to the present invention;

2A is a perspective view of the transmitting terminal of FIG. 1, and FIG. 2B is a sectional view of the transmitting terminal of FIG. 1;

3A is a front view of the receiving terminal of FIG. 1, and FIG. 3B is a side view of the receiving terminal of FIG. 1;

4 is a front view showing another embodiment of the receiving terminal of FIG.

5 is a diagram illustrating bidirectional communication by TDD (Time Division Duplex) between a master and a slave;

6 is a flowchart illustrating an embodiment of a method for measuring temperature by the wireless temperature measuring system of FIG. 1, and

7 is a flowchart illustrating another embodiment of a method for measuring temperature by the wireless temperature measuring system of FIG. 1.

<Description of Symbols for Major Parts of Drawings>

20: transmitting terminal 22: sensor

24: Comparator 26: Transmitter

40: receiver terminal 42: receiver

44: display 46: timer

48: alarm 50: second transmitter

The present invention relates to a wireless body temperature measuring system and a wireless body temperature measuring method using the same, and more particularly, a wireless body which can check the fluctuation state of the body temperature at any time by wearing a thermometer on a predetermined part of the body of the elderly, infant, or patient. A body temperature measuring system and a wireless body temperature measuring method using the same.

The thermometer is divided into a mercury thermometer and a digital thermometer.When measuring the temperature, the thermometer is inserted under the tongue, armpits, anus, etc. in the mouth most sensitive to body temperature in the body. Waiting for abnormalities can measure body temperature.

For this reason, general adults and children can measure the temperature without any difficulty, but infants and young children who have a habit of not maintaining a posture for long due to lack of discernment or expressive ability and strong activity There is a hassle that necessarily requires supervision of guardian.

In particular, infants, infants, senior citizens, or patients are often unable to express their pain directly to others due to lack of expressive ability in changing health conditions from time to time. Although it is necessary to monitor whether the health condition changes by measuring, in practice, it is quite difficult for the guardian to continuously measure the temperature.

The present invention has been made to solve the above problems, by continuously measuring the temperature of the infant or infant, the elderly or the patient, the wireless temperature measurement system that can continuously check the change in their health status and its It is an object to provide a method.

Wireless temperature measuring system according to the present invention for achieving the above object is a sensor for measuring the body temperature of the body in contact with a predetermined part of the body, a comparator for comparing the body temperature measured by the sensor with a set reference value, and the A transmitting terminal having a transmitter for transmitting the measured body temperature as a radio signal when a difference between the body temperature and the reference value is greater than or equal to a predetermined value; And a receiving terminal having a receiver for receiving the radio signal transmitted from the transmitting terminal, and a display for displaying the radio signal received by the receiver.

Preferably, the receiving terminal further includes an alarm that sounds different alarm sounds in stages according to the difference between the body temperature and the reference value.

Preferably, the receiving terminal further includes a timer that counts the current time, and when the radio signal is not received from the receiving terminal, displays the current time through the display.

The receiving terminal may further include a transmitter for converting the alarm sound ringing through the alarm into an alarm signal and transmitting the alarm signal to an external speaker, when the alarm sound ringing through the alarm does not stop within a predetermined time. Preferably, the alarm signal is transmitted to the external speaker. Here, the external speaker is a speaker mounted to the electronic device connected to the receiving terminal.

In addition, the receiving terminal is connected to a plurality of transmitting terminals, it is preferable to display the source of the radio signal received on the display by distinguishing each radio signal transmitted from each of the transmitting terminal.

On the other hand, the wireless body temperature measurement system according to the present invention, (a) measuring the body temperature of the body through a sensor in contact with a predetermined part of the body; (b) comparing the body temperature measured by the sensor with a set reference value; (c) transmitting the measured body temperature as a wireless signal when the difference between the body temperature and the reference value is greater than or equal to a predetermined value; And (d) receiving and displaying the wireless signal transmitted by the step (c) at a place spaced from the sensor by a predetermined distance.

Preferably, the wireless body temperature measurement method further comprises the step of (e) generating different alarm sounds in stages according to the difference between the body temperature and the reference value.

Advantageously, said wireless body temperature measurement method comprises: (f) counting a current time; And (g) displaying the current time counted by step (f) if the difference between the body temperature and the reference value is less than the predetermined value.

The wireless body temperature measuring method may further include converting the generated alarm sound into an alarm signal and transmitting the generated alarm sound to an external device when the alarm sound generated by the step (e) does not stop within a predetermined time. It is preferable to further include.

Preferably, the step (d), (d-1) receiving the body temperature for a plurality of different bodies through a plurality of different sensors as a radio signal, and distinguishing each of the received radio signal ; And (d-2) indicating the source of each radio signal classified by step (d-1).

As a result, the wireless temperature measuring system according to the present invention can continuously measure the temperature of an infant, an infant, an elderly person or a patient, and thus can continuously check the change in their health status.

Hereinafter, with reference to the accompanying drawings will be described in detail the wireless body temperature measurement system and its temperature measurement method.

1 is a block diagram schematically showing a wireless body temperature measurement system according to the present invention. Referring to the drawings, the wireless body temperature measurement system is composed of a transmitting terminal 20 and the receiving terminal 40. Here, the transmitting terminal 20 includes a sensor 22, a comparator 24, and a transmitter 26. The receiving terminal 40 also includes a receiver 42, a display 44, a timer 46, an alarm 48, and a second transmitter 50.

2A is a perspective view of the transmitting terminal of FIG. 1, and FIG. 2B is a sectional view of the transmitting terminal of FIG. The transmitting terminal 20 is provided with a band 21 so that it can be worn on the arm or armpit of the infant or infant, the elderly or the patient. At this time, since the transmitting terminal 20 is mounted on an infant, an infant, an elderly person or a patient, the weight and size thereof need to be minimized. In order to meet such demands, as shown in FIG. 2A, the transmitter side terminal 20 is provided with a battery mounting part 23 for mounting a battery such as a mercury cell on the front thereof, and a straight groove is made of coin or the like. Rotate to open the lid and install the battery. In this case, only the minimum components such as the comparator 24 and the transmitter 26 are mounted inside the transmitting terminal 20 to minimize the weight and size, and prevent waste of power consumption by other unnecessary elements. do.

In addition, since the transmitting terminal 20 should be mounted on the infant or infant, the elderly or the patient for a long time, it is required to transmit and receive data wirelessly by removing the wiring between the receiving terminal 40 and the battery. It needs to be implemented to maximize time. The wireless communication method between the transmitting terminal 20 and the receiving terminal 40 will be described later.

In addition, as shown in FIG. 2B, the sensor 22 is a rear surface of the transmitting terminal 20 so that heat is easily transmitted from the contacted arm or arm when the transmitting terminal 20 is worn on the arm or armpit. It is preferable to be installed in close contact with the.

The sensor 22 contacts a predetermined part of the body to measure the body temperature of the body, and transmits the measured body temperature to the comparator 24.

The comparator 24 compares the body temperature of the body received from the sensor 22 with a predetermined reference value. At this time, since the normal body temperature is 36.5 ??, the reference value of the comparator 24 is preferably set to 36.5 ??.

The transmitter 26 transmits the measured body temperature as a radio signal when the value compared by the comparator 24, that is, the difference between the body temperature and the reference value is more than a predetermined value. For example, the transmitter 26 has a difference between the body temperature and the reference value by 0.1? In the above case, it may be implemented to transmit a radio signal. In this case, the transmitting terminal 20 may include a transmitting alarm (not shown), and may be implemented to sound an alarm whenever the radio signal is transmitted by the transmitter 26.

The receiver 42 provided in the receiving terminal 40 receives a radio signal transmitted from the transmitting terminal 20.

In this case, the receiving terminal 40 includes a timer 46 that counts the current time, and when the wireless signal is not received from the transmitting terminal 20, displays the current time through the display 44. In general, it is preferable to use the receiving terminal 40 as a general clock.

In addition, the receiving terminal 40 preferably includes an alarm 48 that sounds an alarm when a radio signal is received from the transmitting terminal 20. At this time, the alarm 48 may be implemented to sound different alarm sounds according to the difference between the received wireless signal, that is, the body temperature and the reference value set in the comparator 24. For example, the difference between the body temperature and the reference value is 0.1 ?? In the case of transmitting a radio signal in the above case, the alarm 48 divides the loudness of the alarm sound sent out into three stages of A, B, and C from small to loud, and the difference between the body temperature and the reference value is 0.1? ? It can be implemented to emit a loud alarm every time it gets louder. At this time, it is preferable that the alarm sound transmitted by the alarm 48 is implemented as a sound informing that an alarm sound is higher than a low alarm sound level. An embodiment of the receiving terminal 40 is as shown in FIG. That is, as shown in FIG. 3A, the receiving terminal 40 must continuously display the current time through the display 44 or display the received wireless signal, and thus, supply of continuous power is necessary. In addition, since a constant alarm sound must be generated in accordance with the radio signal, it is necessary to supply a large amount of power to the alarm 48. To this end, as shown in Figure 3b, it is preferable that the outlet 52 that can be connected to the AC power is provided on the back of the receiving terminal 40. However, the shape of the outlet 52 for connecting to the AC power source is not limited to that shown, it may be connected via a wire.

In addition, the receiving terminal 40 has a second transmitter 50 for converting the alarm sound ringing through the alarm 48 to the alarm signal to transmit to the external speaker 60, the alarm ringing through the alarm 48 If the sound does not stop within a predetermined time may be implemented to transmit an alarm signal to the external speaker (60). Here, the external speaker 60 may be a speaker mounted on an electronic device such as an audio or television, or may be an independent speaker that amplifies and outputs an alarm sound transmitted through the alarm 48. In addition, the alarm signal transmitted to the external speaker 60 may be transmitted through a wire between the second transmitter 50 and the external speaker 60, or may be transmitted at a radio frequency matching the output frequency of the external speaker 60. have.

In addition, the receiving terminal 40 is preferably provided with a selection key so that the user can select and display the body temperature or the current time received from the transmitting terminal 20.

In addition, the receiving terminal 40 receives data wirelessly from the plurality of transmitting terminals 20, and separates the radio signals transmitted from each transmitting terminal 20 to receive the radio signals received on the display 44. It can be implemented to indicate the source of. In this case, as shown in FIG. 4, the receiving terminal 40 may provide a plurality of source selection keys and may be implemented so that the user selectively selects the transmitting terminal 20 to check the patient's condition. .

On the other hand, the wireless body temperature measurement system according to the present invention, for wireless communication between the transmitting terminal 20 and the receiving terminal 40, or between the receiving terminal 40 and the external speaker 60, Bluetooth (bluetooth) ) Protocol, a Wi-Fi protocol, and a protocol including a UWB (Ultra Wide Band) protocol.

Bluetooth is the code name for wireless data communication technology across telecommunications, networking, computing, and consumer goods. Bluetooth technology replaces the need for multiple cable connections between devices through a single wireless connection within short range.

Wi-Fi is also a logo provided by the Wireless Ethernet Compatibility Association, or Wireless Ethernet Capability Alliance (WECA), for the 802.11b wireless Ethernet standard. Here, 802.11 is a set of specifications for a wireless LAN developed by the Institute of Electrical and Electronics Engineers (IEEE) working group, and four standards include 802.11, 802.11a, 802.11b, and 802.11g. These four specifications all use the Ethernet Protocol Carrier Sense Multiple Access / Collision Avoidance (CSMA / CA), which is an Ethernet protocol. The 802.11b standard is often referred to as Wi-Fi, and while the modulation scheme used in traditional 802.11 is PSK (Phase-Shift Keying), the modulation scheme adopted by 802.11 provides higher data rates, Use complementary code keying (CCK) that is less susceptible to interference.

Ultra-wideband (UWB), also known as wireless digital pulses, is a wireless technology for transmitting large amounts of digital data over a wide spectrum of frequencies at low power over short distances. Ultra-wideband radios can transmit large amounts of data up to 70m with a low power of 0.5mW, as well as pass signals beyond doors and other obstacles that reflect signals at high power and more limited bandwidth. Can transmit

Hereinafter, assuming that the Bluetooth protocol is applied to the present invention, data transmission and reception between the transmitting terminal 20 and the receiving terminal 40 or data transmission between the receiving terminal 40 and the external speaker 60 will be described. .

In general, Bluetooth has a maximum data rate of 1Mbps and a maximum transmission distance of 10m. 1Mbps is a frequency in the category within the 2.4GHz Industrial Scientific Medical (ISM) frequency band that is available to users without a license, and is a transmission rate that can be realized easily and at low cost. In addition, the transmission distance 10m is determined according to the judgment that the transmission distance between the device that the user is carrying and the PC installed in the desk in the office, hospital, and home.

In addition, since Bluetooth is designed to operate in a noisy radio frequency environment, the frequency hopping method of 1600 times per second enables stable data transmission and reception even in noisy radio frequencies.

5 is a diagram illustrating bidirectional communication by TDD (Time Division Duplex) between a master and a slave. Referring to the figure, the length of each channel allocated to the timeslot is 625 ?? s = 1/1600 second. The number of timeslots is determined by the Piconet master's Bluetooth clock. In addition, the timeslot allows the master and the slave to send packets alternatively. That is, the master transmits the packet only in the even numbered timeslot, and the slave transmits the packet only in the odd numbered timeslot. In addition, a packet transmitted by a master or a slave must be implemented within five timeslots.

6 is a flowchart illustrating an embodiment of a method for measuring temperature by the wireless temperature measuring system of FIG. 1. Referring to the drawings, the transmitting terminal 20 is worn on a predetermined part of the body, such as the arm or armpit of an infant, an infant, an elderly person or a patient, and measures the body temperature of the body through a sensor 22 in contact with the body. (S101). At this time, as described above, the sensor 22 is mounted on the rear surface of the transmitting terminal 20 to be in contact with the body through the band 21.

The comparator 24 compares the body temperature measured by the sensor 22 with a preset reference value (S103). At this time, the reference value is preferably set to a normal body temperature, that is, 36.5 ??.

When the difference between the body temperature and the reference value is greater than or equal to the predetermined value by the comparator 24 (S105), the transmitter 26 transmits the body temperature measured by the sensor 22 to the receiving terminal 40 as a wireless signal (S107). .

The receiver 42 of the receiving terminal 40 receives the radio signal transmitted from the transmitting terminal 20 and transmits the received radio signal to the display 44 for display (S109). In addition, the receiver 42 transmits the radio signal transmitted from the transmitting terminal 20 to the alarm 48.

The alarm 48 generates an alarm sound in stages according to the magnitude of the difference between the body temperature and the reference value (S111). That is, the measured body temperature is 0.1? When a wireless signal is received whenever an abnormal difference occurs, the alarm 48 preferably generates an alarm sounding an emergency whenever the difference between the measured body temperature and the reference value increases at a predetermined interval. For this purpose, the alarm 48 preferably includes a second comparator (not shown) whose reference value is set to the same value as the comparator 24 provided in the transmitting terminal 20.

As a result, a guardian who is located at a predetermined distance from the infant or the infant or the elderly or the patient can immediately recognize that there is a problem with the health condition of the infant or the infant or the elderly or the patient.

If the alarm sound generated by the alarm 48 is not interrupted within a predetermined time by the guardian, the second transmitter 50 converts the alarm sound generated by the alarm 48 into an alarm signal to the external speaker 60. It transmits (S113). In this case, the external speaker 60 is a speaker to which power is applied and refers to a speaker capable of transmitting and receiving data with the second transmitter 50 in a wired or wireless manner. That is, when the guardian hears an alarm by the alarm 48 while the guardian is listening to television or audio, and the guardian does not hear the alarm, the second transmitter 50 sounds the alarm generated by the alarm 48. Output through television or audio that the guardian is listening to allows the guardian to be informed of changes in the health of the infant, infant, elderly or patient.

If the difference between the body temperature and the reference value is smaller than the predetermined value, the transmitting terminal 20 blocks the transmission of data to the receiving terminal 40. That is, in this case, the body temperature measured by the sensor 22 is not transmitted to the receiving terminal 40. As a result, the transmitting terminal 20 can reduce the power consumed due to the transmission of the wireless data, thereby extending the use time.

At this time, the receiving terminal 40 counts the current time through the timer 46 (S115), and displays the counted current time on the display 44 (S117). Thus, when the health of the infant or infant, the elderly or the patient is normal, the receiving terminal 40 may be used as a general watch.

7 is a flowchart illustrating another embodiment of a method for measuring temperature by the wireless temperature measuring system of FIG. 1. Referring to the drawings, the receiving terminal 40 may transmit and receive data with the plurality of transmitting terminals 20. That is, the transmitting terminal 20 may be worn on each body part of the plurality of infants or infants, the elderly or the patient, and may measure the body temperature of the plurality of bodies through the respective sensors (S201).

The comparator 24 of each transmitting side terminal 20 compares the body temperature measured by the sensor 22 with a preset reference value (S203). At this time, the reference value set in each comparator 24 is preferably set equal to the normal body temperature, that is, 36.5 ??.

When it is determined by the comparator 24 that the difference between the body temperature and the reference value is greater than or equal to the predetermined value by the comparator 24 (S205), the transmitter 26 of each transmitting side terminal 20 receives the body temperature measured by the sensor 22 as a radio signal. The transmission is sent to the side terminal 40 (S207).

The receiver 42 of the receiving terminal 40 may receive radio signals transmitted from the plurality of transmitting terminals 20. At this time, the receiving terminal 40 distinguishes each body temperature received from each transmitting terminal 20 (S209). That is, the receiving terminal 40 distinguishes the received radio signal by searching an address given to each packet with respect to the radio signal received from each transmitting terminal 20, and for each radio signal received. The source is displayed on the display 44 (S211), and the received body temperature is displayed on the display 44 (S213). In this case, when the body temperature received from the transmitting terminal 20 is higher than the set temperature, an alarm is output, and the room number, bed number, etc. may be displayed to blink to inform the source of the output alarm (S215). In addition, the receiving terminal 40 may be implemented to transmit and receive data with a computer managing a patient, infant, infant, and the like. In this case, the receiving terminal 40 transmits the data received from the transmitting terminal 20 to the connected computer, thereby facilitating the state analysis of the patient, infant, infant, etc. through the computer.

As a result, when the wireless body temperature measuring system according to the present invention is installed in a hospital or nursery school, it is possible to simultaneously monitor a large number of infants, infants, senior citizens, patients, and the like, and monitor each health state.

When the difference between the body temperature and the reference value of each transmitting terminal 20 installed in a plurality of infants or infants or the elderly or the patient is smaller than a predetermined value, each transmitting terminal 20 is sent to the receiving terminal 40. Block the transmission of data. That is, in this case, the body temperature measured by the sensor 22 is not transmitted to the receiving terminal 40. As a result, each transmitting terminal 20 can reduce the power consumed due to the transmission of the wireless data, thereby extending the use time.

At this time, the receiving terminal 40 counts the current time through the timer 46 (S217), and displays the counted current time on the display 44 (S219). Thus, when all infants or infants, the elderly or the patient's health is normal, the receiving terminal 40 may be used as a general watch.

According to the present invention, the wireless body temperature measurement system not only continuously monitors the health status of infants, infants, the elderly, or patients, but also minimizes the inconvenience of wearing by minimizing the weight and size of the transmitting terminal. Make sure

In addition, the wireless body temperature measurement system according to the present invention allows the transmitting terminal to transmit data only when there is a change in measured body temperature, thereby minimizing power consumed when transmitting wireless data.

In addition, the wireless temperature measurement system according to the present invention, by generating an alarm sound in stages in accordance with the change in the body temperature of infants, infants, the elderly or the patient, enables the guardian to respond quickly.

In addition, the wireless body temperature measurement system according to the present invention can receive data from a plurality of transmitting terminal terminals, so that it is possible to monitor the health status of a large number of people at the same time in a hospital or nursery school.

Claims (12)

A sensor for measuring body temperature of the body in contact with a predetermined part of the body, a comparator for comparing the body temperature measured by the sensor with a set reference value, and the measured body temperature measured when the difference between the body temperature and the reference value is greater than or equal to a predetermined value. A transmitter terminal having a transmitter for transmitting a radio signal; And And a receiving terminal having a receiver for receiving the radio signal transmitted from the transmitting terminal, and a display for displaying the radio signal received by the receiver. The method of claim 1, wherein the receiving terminal, The wireless body temperature measurement system further comprises an alarm that sounds different alarm sounds in stages according to the difference between the body temperature and the reference value. The method of claim 2, wherein the receiving terminal, It further includes a timer that counts the current time, And if the wireless signal is not received from the receiving terminal, displaying the current time on the display. The method of claim 3, wherein the receiving terminal, The transmitter further includes a transmitter for converting the alarm sound ringing through the alarm to an alarm signal to transmit to an external speaker, And transmitting the alarm signal to the external speaker when the alarm sound is not stopped within a predetermined time. The method of claim 4, wherein The external speaker is a wireless body temperature measurement system, characterized in that mounted to the electronic device connected to the receiving terminal. The method of claim 3, wherein The receiving terminal wirelessly receives data from a plurality of transmitting terminals, distinguishes each radio signal transmitted from each transmitting terminal, and displays a source of the radio signal received on the display. Wireless thermometer system. (a) measuring the body temperature of the body through a sensor in contact with a predetermined part of the body; (b) comparing the body temperature measured by the sensor with a set reference value; (c) transmitting the measured body temperature as a wireless signal when the difference between the body temperature and the reference value is greater than or equal to a predetermined value; And and (d) receiving and displaying the wireless signal transmitted by the step (c) at a place spaced from the sensor by a predetermined distance. The method of claim 7, wherein (e) generating a different alarm sound step by step according to the difference between the body temperature and the reference value. The method of claim 8, (f) counting the current time; And and (g) if the difference between the body temperature and the reference value is less than the predetermined value, displaying the current time counted by step (f). The method of claim 8, (f) if the alarm sound generated by step (e) does not stop within a predetermined time, converting the generated alarm sound into an alarm signal and transmitting the wireless signal to an external device. Body temperature measurement method. The method of claim 8, wherein step (d) (d-1) receiving body temperature of a plurality of different bodies as a wireless signal through a plurality of different sensors, and distinguishing each of the received wireless signals; And (d-2) A wireless body temperature measurement method comprising the step of displaying the source of each of the wireless signal divided by the step (d-1). The method of claim 11, Wireless database temperature measurement method characterized in that the database of each wireless signal received through the plurality of different sensors, and analyzes the condition of the patient based on each of the wireless signal in the database.

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