KR20160123794A - Method for providing service of tracking location using smart sensor - Google Patents

Abstract

Disclosed is a method for providing a location tracking service using a smart sensor. A relay device includes a gyro sensor, an acceleration sensor, and a terrestrial magnetism sensor. Sensor values and RSSI signals measured by the gyro sensor, the acceleration sensor, and the terrestrial magnetism sensor are received from a beacon using a low power Bluetooth (BLE). A device of providing a location tracking service calculates a separation distance between the beacon and the relay device from the RSSI signals, and calculates the movement distance and movement direction of the beacon from the sensor values. So, the separation of objects or children from a protection area can be prevented.

Description

TECHNICAL FIELD [0001] The present invention relates to a method of providing a location tracking service using a smart sensor,

The present invention relates to a method of providing a location tracking service using a smart sensor, and more particularly, to a method of locating a target to which a short range communication device is attached using a short range communication device having a motion sensor and providing a service .

Recently, more and more people are carrying expensive equipment such as bicycles, notebooks, and tablets. However, social problems have also increased. The number of bicycle theft incidents has increased by 45% from 19,969 in 2011 to 15,951 in 2012, and the number of cases reported by losers is estimated to be higher . There is no policy to prevent burglary that should be carried out with bicycle registration system.

According to a study conducted in the United States by a social loss, an average of 55 minutes is spent on finding a thing during the day. It takes about 12 days to spend for a year.

In addition, there is a need for a solution to the loss and disappearance accidents of the elderly with dementia, children, companion animals, etc. that need protection and monitoring. The average number of lost dogs per day is reported to be at least 12, and about 400 dogs are reported per year.

According to the National Police Agency, the number of disappearances reported in 2013 is as high as 30,869, and the index of fear of crime such as disappearance, kidnapping, and confinement is increasing every year. As it is the case of the recent Suwon murder case, it has been found at the end of the 10 hour search operation centering on the residential area near the base station because the range of the location information and the location based on the base station based GPS are too large.

In order to solve the above problems, there is a need for location-based services in order to protect the objects and to cope with safety monitoring or loss incidents. SUMMARY OF THE INVENTION It is an object of the present invention to provide a short distance communication device having a motion sensor, for example, a gyro sensor, an acceleration sensor and a geomagnetic sensor attached to a target, In order to provide a location tracking service.

According to an aspect of the present invention, there is provided a method of providing a location tracking service, the device including a gyro sensor, an acceleration sensor and a geomagnetic sensor, and a Bluetooth low energy Periodically receiving the sensor values and the RSSI signal from a relay device that receives the sensor values measured by the gyro sensor, the acceleration sensor, and the geomagnetic sensor and the RSSI signal from the used beacon; Calculating a separation distance between the relay apparatus and the beacon from the RSSI signal; And calculating a moving direction and a moving distance of the beacon from the sensor values.

A method of providing a location tracking service includes: generating a beacon departure notification signal when the location tracking service providing apparatus fails to receive the RSSI signal from the relay apparatus; Determining a predicted movement position or movement path of the beacon based on at least one of sensor values, RSSI signal and the predetermined time that the position location service providing apparatus has received for a predetermined time; And the location tracking service providing apparatus may further include a step of externally transmitting the departure notification signal of the beacon and the determined estimated moving location or information on the moving route.

A method of providing a location tracking service includes: generating emergency notification information when the location tracking service providing device receives the RSSI signal from the relay device for a predetermined time, but fails to receive the sensor values; And the location-tracking-service providing apparatus transmits the generated emergency notification information to the outside.

According to the present invention, when an object is stolen or lost, or when a protected position of a protected object such as a child is released, an alarm can be prevented, and even if the object is lost due to an expected position or route, There is an effect that can be.

In addition, when there is no movement of the elderly patient, it is an urgent matter that the life of the patient can be preserved by rapidly contacting the guardian or the related institution.

In addition, there is an effect that a plurality of relay devices recognize a local communication device and recognize an accurate position, thereby acting as a social safety net.

1 is a flowchart illustrating a method of providing a location tracking service according to an embodiment of the present invention.
2 shows a protocol stack of BLE.
3 is a flowchart illustrating a method of providing a location tracking service according to another embodiment of the present invention.
4 is a flowchart illustrating a method of providing a location tracking service according to another embodiment of the present invention.
5 is a block diagram of a system for providing location tracking services according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart illustrating a method of providing a location tracking service according to an embodiment of the present invention.

Referring to FIG. 1, in step 110, an apparatus for performing a location tracking service providing method (hereinafter referred to as a location tracking service providing apparatus) receives a beacon from a beacon, a sensor value measured by an acceleration sensor and a geomagnetic sensor And the RSSI signal from the relay device that has received the RSSI (Received Signal Strength Indicator) signal.

The beacon, which is a smart sensor according to the present invention, is capable of communicating with devices within a short distance by a short range wireless communication small device. In the present invention, the beacon includes a gyro sensor, an acceleration sensor, and a geomagnetic sensor, which are motion sensors. The gyro sensor is an angular velocity sensor that detects the angular velocity of the object. A gyro sensor is a sensor that measures the angle of an object in units of time based on one axis. A gyro sensor is also called a gyroscope. Using the gyro sensor, you can see if the beacon is moving left or right or up and down. The acceleration sensor is a sensor that measures the acceleration of a moving object. By using the acceleration sensor, the travel distance of the beacon can be calculated. The geomagnetic sensor is a sensor that can detect the direction of the magnetic field generated by the earth and detect the orientation like a compass. Using the geomagnetic sensor, you can know the moving direction of the beacon. In the present invention, it is preferable to use a three-axis gyro sensor, a three-axis acceleration sensor, and a three-axis geomagnetic sensor.

Further, in the present invention, it is preferable that the beacon is communicated with the relay apparatus by using Bluetooth low energy (BLE). Low-power Bluetooth is an ultra-low-power short-range wireless personal communication network technology, ultra-low-power and ultra-modular, and emerging communication technology supporting Bluetooth 4.0. Low-power Bluetooth features include low-cost production, low power operation, simplified device connectivity, and reduced packet size and channel count.

2 shows a protocol stack of BLE.

Referring to FIG. 2, the LL (Link Layer) layer is used for establishing and controlling a radio link between two devices. The HCI (Hardware Controller Interface) layer is used for communication between the controller and the host. layer protocol provides a data service at a higher level and divides the packets to be sent to the controller or reassembles received packets. The SM (Security Manager) layer is used for encrypted user authentication. The ATT (Attribute Protocol) layer has its own attributes. Attributes assigned to the ATT determine attributes and services. The GATT (Generic Attribute Protocol) layer uses ATT (Attribute Protocol) The GAP (Generic Access Profile) layer performs the function of defining the setting of the property value, the reading, the writing, the notification, and the indication characteristic. Used for ringing and linking.

Low-power Bluetooth uses 2.4GHz ISM, 40 channels, and some of them send and receive data.

In the present invention, the communication technology is not limited to the low-power Bluetooth, but the short-range dedicated communication method (DSRC), ultrasonic wave, infrared ray, conventional Bluetooth, CDMA, LTE, WiFi and LiFi may also be used.

The relay apparatus is a relay apparatus that scans a beacon to receive a signal from the beacon and transmits the received signal to the location tracking service providing apparatus. The relay device may be a fixed device fixed at a predetermined place, or may be a mobile device such as a smart phone.

The relay apparatus may further receive a unique identifier of the beacon from the beacon. (Or measurement value) of the gyro sensor received from the beacon, the sensor value of the acceleration sensor, the sensor value of the geomagnetic sensor, the RSSI signal, and the unique identifier information to the location tracking service providing apparatus communicating with the relay apparatus.

In step 120, the location tracking service providing apparatus calculates the separation distance between the relay apparatus and the beacon from the RSSI signal received from the relay apparatus. The location of the beacon is predetermined according to the RSSI signal and stored in the location tracking service providing device. The location tracking service providing device analyzes the RSSI signal to determine the distance corresponding to the signal strength.

In step 130, the location tracking service providing apparatus calculates the movement direction and the movement distance of the beacon based on the sensor value (or measurement value) of the gyro sensor, the sensor value of the acceleration sensor, and the sensor value of the geomagnetism sensor. The location tracking service providing device can grasp the up / down / left / right movement of the beacon from the gyro sensor value, can grasp the movement distance of the beacon with time from the acceleration sensor, and can grasp the azimuth angle of the beacon from the geomagnetic sensor. The moving distance may be calculated more accurately using the sensor value of the acceleration sensor and the RSSI. The location tracking service providing device can estimate the relative position of the beacon by comparing the sensor values of the previously received motion sensors and grasping the moving distance and the moving direction of the beacon. After the accurate location of the beacon is determined, the location tracking service providing apparatus can grasp the accurate position even if the beacon moves. The exact location of the beacon may be ascertained using algorithms such as triangulation or square survey when a plurality of repeaters scan the beacon. Also, the location tracking service providing device performs beacon position tracking using a step detection technique, a stride estimation technique, a walking navigation algorithm using a forward direction estimation technique, a DR correction technique, a map matching algorithm using an orthogonal matching and an arc matching technique You may.

In step 140, the location tracking service providing device transmits the distance of the calculated beacon, the moving direction of the beacon, and the travel distance to the terminal where the location tracking service application is installed. The terminal may be a smart phone or a personal computer. When a smart phone is used, the smart phone may also perform the role of a relay device.

3 is a flowchart illustrating a method of providing a location tracking service according to another embodiment of the present invention.

Figure 3 shows the steps performed after the steps of Figure 1 are performed.

Referring to FIG. 3, in step 310, when the location tracking service providing apparatus fails to receive the RSSI signal from the relay apparatus, the beacon departure notification signal is generated. When the location tracking service providing apparatus fails to receive the RSSI signal from the relay apparatus, the beacon is out of the scanning range of the relay apparatus, and the relay apparatus can not receive the signal from the beacon.

In step 320, the location tracking service providing device moves the time information related to the interval between the reception times and at least one of the sensor values, the RSSI signals of the motion sensors received before, and determines the expected movement position or the movement route of the beacon. The location tracking service providing device can recognize the moving direction and the moving distance of the beacon, that is, the moving route, using the previous motion sensor sensor values and / or the RSSI signal. When the moving route is substituted into the time, the estimated moving route is calculated. The location tracking service providing device calculates an expected travel route per hour from the location where the RSSI was last received.

In step 330, the location tracking service providing device transmits the departure notification signal of the generated beacon and the determined estimated movement location or information on the movement route to the terminal where the location tracking service application is installed. This allows the user to quickly recognize when a beacon-mounted object (e.g., a wallet, a bicycle, a child, a companion animal, etc.) is lost or stolen, I can find it.

4 is a flowchart illustrating a method of providing a location tracking service according to another embodiment of the present invention.

Figure 4 shows the steps performed after the steps of Figure 1 are performed.

Referring to FIG. 4, in step 410, when the location tracking service providing apparatus receives the RSSI signal from the relay apparatus for a predetermined time, but does not receive the sensor values of the motion sensors, it generates the emergency notification information. The RSSI signal is received but the beacon does not move when the sensor value of the motion sensor, in particular, the acceleration sensor, is not received. The present embodiment is applied to a person who is likely to read consciousness such as the elderly living alone, a dementia patient, or a sick person. In the case of receiving the RSSI signal but not receiving the sensor value of the motion sensor, particularly, the acceleration sensor, it is highly likely that the persons have lost consciousness. Therefore, the location tracking service providing device recognizes this as an emergency situation and generates emergency alert information .

In step 420, the location tracking service providing device transmits the generated emergency notification information to the terminal where the location tracking service application is installed. Alternatively, emergency alert information may be transmitted to a predetermined guardian telephone or social group or hospital.

Although not shown in the drawing, when the relay device scans the beacon in which the departure signal is registered, the relay device notifies the location tracking service providing device of the beacon, and the location tracking service providing device can recognize the location of the beacon have.

According to another embodiment of the present invention, when the beacon is set to the monitoring mode, when the movement is recognized from the received sensor value, the location tracking service providing device may transmit the emergency notification information to the terminal equipped with the location tracking service application . In this case, when the movement of the beacon is detected, the beacon itself may output voice or light.

5 is a block diagram of a system for providing location tracking services according to an embodiment of the present invention.

5, the location tracking service providing system 500 includes a beacon 510, a relay apparatus 520, a location tracking service providing apparatus 530, and a terminal 540, and the location tracking service providing apparatus 530 Includes a receiving unit 532, a control unit 534, a storage unit 536, and a transmitting unit 538.

The receiving unit 532 of the location tracking service providing apparatus receives the sensor values and the RSSI signals measured by the gyro sensor, the acceleration sensor and the geomagnetic sensor mounted on the beacon 510 from the beacon 510, Values and the RSSI signal periodically.

The beacon 510 is a short-range wireless communication handheld device capable of communicating with devices within short range. In the present invention, the beacon 510 includes a gyro sensor, an acceleration sensor, and a geomagnetic sensor, which are motion sensors. The gyro sensor is an angular velocity sensor that detects the angular velocity of the object. A gyro sensor is a sensor that measures the angle of an object in units of time based on one axis. A gyro sensor is also called a gyroscope. Using the gyro sensor, you can see if the beacon is moving left or right or up and down. The acceleration sensor is a sensor that measures the acceleration of a moving object. By using the acceleration sensor, the travel distance of the beacon can be calculated. The geomagnetic sensor is a sensor that can detect the direction of the magnetic field generated by the earth and detect the orientation like a compass. Using the geomagnetic sensor, you can know the moving direction of the beacon. In the present invention, it is preferable to use a three-axis gyro sensor, a three-axis acceleration sensor, and a three-axis geomagnetic sensor.

Also, in the present invention, the beacon 510 preferably communicates with the relay device 520 using Bluetooth low energy (BLE). Low-power Bluetooth is an ultra-low-power short-range wireless personal communication network technology, ultra-low-power and ultra-modular, and emerging communication technology supporting Bluetooth 4.0. Low-power Bluetooth features include low-cost production, low power operation, simplified device connectivity, and reduced packet size and channel count. Low-power Bluetooth uses 2.4GHz ISM, 40 channels, and some of them send and receive data.

In the present invention, the communication technology is not limited to the low-power Bluetooth, but the short-range dedicated communication method (DSRC), ultrasonic wave, infrared ray, conventional Bluetooth, CDMA, LTE, WiFi and LiFi may also be used.

The relay apparatus 520 is a relay apparatus that scans the beacon 510 to receive a signal from the beacon 510 and transmits the received signal to the location tracking service providing apparatus 530. The relay device 520 may be a fixed device fixed at a predetermined place, or may be a smartphone, that is, a terminal 540 in which a location tracking service application to be described below is driven.

The relay apparatus 520 may further receive a unique identifier of the beacon from the beacon 510. [ (Or measurement value) of the gyro sensor received from the beacon 510, the sensor value of the acceleration sensor, the sensor value of the geomagnetic sensor, the RSSI (Received Signal Strength Indicator) Or to a location tracking service providing device 530 capable of communicating wirelessly.

The control unit 534 of the location tracking service providing apparatus calculates the separation distance between the relay apparatus 520 and the beacon 510 from the RSSI signal received from the relay apparatus 520. [ The location of the beacon according to the RSSI signal is predetermined and stored in the storage unit 536 of the location tracking service providing apparatus. The control unit 534 of the location tracking service providing apparatus analyzes the RSSI signal to determine the distance corresponding to the signal strength.

Then, the control unit 534 of the location tracking service providing apparatus determines the moving direction and the moving distance of the beacon 510 based on the sensor value (or the measured value) of the gyro sensor, the sensor value of the acceleration sensor, and the sensor value of the geomagnetism sensor . The control unit 534 of the location tracking service providing apparatus can grasp the up / down and left / right movement of the beacon 510 from the gyro sensor value and can grasp the moving distance of the beacon 510 according to the time from the acceleration sensor, It is possible to grasp the azimuth angle of the antenna 510. The moving distance may be calculated more accurately using the sensor value of the acceleration sensor and the RSSI. The control unit 534 of the location tracking service providing apparatus can estimate the relative position of the beacon 510 by comparing the sensor values of the previously received motion sensors and grasping the moving distance and the moving direction of the beacon 510. [ After the accurate position of the beacon 510 is detected, the position tracking service providing apparatus can grasp the accurate position even if the beacon 510 moves. The exact location of the beacon 510 may be determined using algorithms such as triangulation or square survey when a plurality of repeaters 520 scan the beacon 510. In addition, the control unit 534 of the location-tracking service providing apparatus may use a walking detection technique, a stride estimation technique, a walking navigation algorithm or a DR correction technique using a traveling direction estimation technique, a map matching algorithm using orthogonal matching and arc matching, It may perform the tracking of the location of the mobile terminal 510.

The transmission unit 538 of the location tracking service providing apparatus transmits the calculated distances to the beacon, the beacon moving direction, and the travel distance to the terminal 540 in which the location tracking service application is installed. The terminal may be a smart phone or a personal computer. When a smart phone is used, the smart phone may also perform the role of a relay device.

When the receiving unit 532 of the location tracking service providing apparatus fails to receive the RSSI signal from the relay apparatus 520, the beacon 510 generates a departure notification signal. When the location tracking service providing apparatus 530 fails to receive the RSSI signal from the relay apparatus 520, the beacon 510 is moved out of the scan area of the relay apparatus 520 and the relay apparatus 520 is moved from the beacon 510 The signal is not received.

The control unit 534 of the location tracking service providing apparatus moves time information related to at least one of the sensor values and the RSSI signals of the motion sensors received before and the intervals of the reception times, . The control unit 534 of the location tracking service providing apparatus can recognize the movement direction and the movement distance of the beacon, that is, the movement route, using the previous motion sensor sensor values and / or RSSI signals. When the moving route is substituted into the time, the estimated moving route is calculated. The control unit 534 of the location service providing apparatus calculates an estimated travel route per hour from the position where the RSSI was last received.

The transmission unit 538 of the location tracking service providing apparatus transmits the generated notification signal of the beacon of the beacon and the determined estimated movement position or information about the movement route to the terminal 540 in which the location tracking service application is installed. This allows the user to quickly recognize when a beacon-mounted object (e.g., a wallet, a bicycle, a child, a companion animal, etc.) is lost or stolen, I can find it.

When the receiver 532 of the location tracking service providing device receives the RSSI signal from the relay device 520 for a predetermined time, but fails to receive the sensor values of the motion sensors, it generates the emergency notification information. When the RSSI signal is received but the sensor value of the motion sensor, in particular, the acceleration sensor, is not received, there is no movement of the beacon 510. The present embodiment is applied to a person who is likely to read consciousness such as the elderly living alone, a dementia patient, or a sick person. When the sensor value of the motion sensor, in particular, the acceleration sensor, is not received, the control unit 534 of the device for providing location tracking service recognizes it as an emergency situation because the RSSI signal is received, And generates notification information.

The transmitter 538 of the location tracking service providing device transmits the generated emergency notification information to the terminal 340 in which the location tracking service application is installed. Alternatively, the transmission unit 538 of the location tracking service providing apparatus may transmit emergency notification information to a predetermined guardian telephone or a social group or a hospital.

When the relay apparatus 520 scans the beacon 510 in which the departure signal is registered, the relay apparatus 520 informs it to the location tracking service providing apparatus 530. The location tracking service providing apparatus 530 transmits the beacon 510 ), It is possible to respond to a lost accident.

In another embodiment of the present invention, when the beacon 510 is set in the monitoring mode, the location tracking service providing device 530 may receive the location information from the terminal 540 installed with the location tracking service application, Emergency notification information may be transmitted. In this case, when the movement of the beacon 110 is detected, the beacon 110 itself may also output voice or light.

The location tracking service providing method as described above can also be implemented as computer readable codes on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording media in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like. The computer readable recording medium may also be distributed over a networked computer system so that computer readable code can be stored and executed in a distributed manner. And, functional programs, codes, and code segments for implementing the disk management method can be easily deduced by the programmers of the present invention.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

510: Beacon 520: Relay device
530: Positioning service providing device
532: Receiving unit 534:
536: storage unit 538:
540:

Claims (3)

A method for providing a location tracking service in a location tracking service providing apparatus,
Wherein the location tracking service providing apparatus includes a gyro sensor, an acceleration sensor, and a geomagnetic sensor, and receives sensor values and RSSI signals measured by the gyro sensor, the acceleration sensor, and the geomagnetic sensor from a beacon using low- Periodically receiving the sensor values and the RSSI signal from the received relay device;
Calculating a separation distance between the relay apparatus and the beacon from the RSSI signal;
And calculating a moving direction and a moving distance of the beacon from the sensor values. The method according to claim 1,
Generating a beacon departure notification signal when the location tracking service providing apparatus fails to receive the RSSI signal from the relay apparatus;
Determining a predicted movement position or movement path of the beacon based on at least one of sensor values, RSSI signal and the predetermined time that the position location service providing apparatus has received for a predetermined time; And
Wherein the location tracking service providing apparatus further comprises a step of externally transmitting the beacon departure notification signal and the determined estimated movement position or information on the movement route. The method according to claim 1,
Generating emergency alert information when the location tracking service providing apparatus receives the RSSI signal from the relay apparatus for a predetermined time but fails to receive the sensor values; And
Wherein the location tracking service providing device transmits the generated emergency notification information to the outside.

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