JP6730087B2 - Monitoring system - Google Patents

Description

The embodiment of the present invention relates to a monitoring system capable of confirming an abnormality in a monitored person, and a sliding door opening/closing device used in the monitoring system.

In recent years, for example, in a facility or a residence, there has been proposed a monitoring system capable of monitoring a monitoring target person using a mobile robot. For example, in the security system of Patent Document 1, an image sensor, that is, a video camera or other various sensors is provided in a facility or a residence, and behavior of a resident or the like is estimated based on information obtained from the various sensors. Then, this security system sets a degree of attention for each area to be monitored, and when the behavior of a resident or the like is confirmed in the area having a high degree of attention, increases the frequency of patrol of the mobile robot in the area. And so on. As a result, it is possible to focus on the area where an abnormality is likely to occur, as a result of which it is possible to quickly detect the occurrence of the abnormality, as compared with the case where the entire area to be monitored is patroled evenly. ..

However, the security system described above does not directly detect the state of the resident or the like. Therefore, in the security system that was operated above, when an abnormality occurs in a resident or the like in a low attention area, for example, when a resident or the like is sick and an abnormality such as a heart attack occurs in a state of sleeping in a bed. Therefore, there is a high possibility that it cannot be detected by the sensor provided in the living room. In this case, for example, when the attention level of the bed is set to be low, the patrol frequency of the mobile robot is also low, and as a result, the discovery of the abnormality may be delayed.

JP, 2004-185080, A

Therefore, in the case where an abnormality occurs in a person to be monitored, a monitoring system that allows the monitoring person to quickly confirm the abnormality, and a sliding door opening/closing device used in the monitoring system are provided.

The monitoring system includes a biometric information acquisition device, a mobile robot, a monitoring device, and a sliding door opening/closing device. The biometric information acquisition device includes a biometric information acquisition unit capable of acquiring biometric information of a monitoring target person, a first communication unit capable of communicating via an electric communication line, and a case where the biometric information is out of a preset normal range. An abnormal signal transmitting unit that transmits an abnormal signal, and is attachable to the person to be monitored. The mobile robot includes a second communication unit capable of communicating via the electric communication line and a moving mechanism unit capable of autonomously moving within a specific area. The monitoring device has a third communication unit capable of communicating via the telecommunication line. The sliding door opening/closing device is attached to a sliding door in the living room of the person to be monitored, is configured to be directly communicable with the mobile robot without going through the electric communication line, and automatically operates the sliding door according to an instruction from the mobile robot. It is possible to switch between an automatic door state that can be opened and closed and a manual door state that can be opened and closed manually. When the mobile robot receives the abnormal signal, the mobile robot moves toward the biological information acquisition device to which the abnormal signal is transmitted, and when the mobile robot enters the room of the monitored person, the front side of the sliding door. At the position of 1, and communicates directly with the sliding door opening/closing device to switch the sliding door opening/closing device to the automatic door state, open the sliding door, and enter the living room, the biological information acquisition device or the mobile robot. Alternatively, when an operation for canceling the abnormality is input to any of the monitoring devices, the user exits the room and sends a leaving completion signal when the leaving is completed. The sliding door opening/closing device maintains the sliding door in an open state while the mobile robot is in the living room, and the mobile robot exits the living room to output a leaving completion signal transmitted from the mobile robot. Upon reception, the sliding door is closed and then the sliding door is put in the manual state.

The sliding door opening/closing device rotationally drives a receiving unit capable of receiving a signal from an external device, a rack gear provided in the sliding door along the opening/closing direction of the sliding door, a pinion gear fittable with the rack gear, and the pinion gear. Based on a signal received by the motor and the receiving unit, the rack gear and the pinion gear are fitted to each other, and the rotation of the motor is transmitted to the rack gear to automatically open and close the sliding door. And a switching mechanism section capable of switching between a state and a manual door state in which the sliding door can be manually opened and closed by releasing the fitting between the rack gear and the pinion gear.

Block diagram showing an example of the electrical configuration of a monitoring system according to one embodiment The figure which shows notionally the structure of the sliding door opening/closing apparatus about the monitoring system by one Embodiment. The flowchart which shows an example of the control content performed with a biometric information acquisition apparatus about the monitoring system by one Embodiment. A flow chart showing an example of control contents performed by the monitoring device in the monitoring system according to the embodiment. Flowchart showing an example of control contents performed by the mobile robot in the monitoring system according to the embodiment (Part 1) Flowchart showing an example of control contents performed by the mobile robot in the monitoring system according to the embodiment (Part 2) Flowchart showing an example of control contents performed by the mobile robot in the monitoring system according to the embodiment (No. 3) The flowchart which shows an example of the control content performed with the sliding door opening/closing apparatus about the monitoring system by one Embodiment. A plan view (1) conceptually showing a mobile robot, a sliding door opening/closing device, and an operation state of a monitoring system according to an embodiment. A plan view (part 2) conceptually showing a mobile robot, a sliding door opening/closing device, and an operation state of a monitoring system according to an embodiment. A plan view (3) conceptually showing a mobile robot, a sliding door opening/closing device, and an operation state of a monitoring system according to an embodiment. A plan view (part 4) conceptually showing a mobile robot, a sliding door opening/closing device, and an operation state of a monitoring system according to an embodiment. A plan view (part 5) conceptually showing a mobile robot, a sliding door opening/closing device, and an operation state of a monitoring system according to an embodiment. Plan view (6) conceptually showing the mobile robot, the sliding door opening/closing device, and the operating state of the monitoring system according to the embodiment. A plan view (part 7) conceptually showing a mobile robot, a sliding door opening/closing device, and an operation state of a monitoring system according to an embodiment.

An embodiment of the present invention will be described below with reference to the drawings.
The monitoring system 1 shown in FIG. 1 is a system capable of monitoring the states of a large number of persons to be monitored by a small number of persons, and can be applied to, for example, nursing care facilities, hospitals, and even ordinary houses. The person to be monitored is not limited to humans, and may be pet animals such as dogs and cats. Moreover, the number of persons to be monitored is not limited to the case where there are a plurality of persons, and may be one person.

As shown in FIG. 1, the monitoring system 1 includes a plurality of biological information acquisition devices 10, a mobile robot 20, a monitoring device 30, and a sliding door opening/closing device 40. Each of the biometric information acquisition devices 10, the mobile robot 20, and the monitoring device 30 are communicably connected to each other via an electric communication line 2 configured to include, for example, the Internet, a telephone line, a LAN line, or the like. .. The telecommunication line 2 may be wired or wireless. In the following, details of each component will be described.

[Biological information acquisition device]
The biometric information acquisition device 10 is a device that can acquire the biometric information of the monitoring target person. The form of the biometric information acquisition device 10 is, for example, a wristwatch type, a pendant type, a belt type, an eyeglass type, a choker type, a helmet type, or the like, and is configured to be attachable to the body of the monitored person. As shown in FIG. 1, the biometric information acquisition device 10 includes a first control unit 11, a first communication unit 12, a position information acquisition unit 13, a biometric information acquisition unit 14, and an abnormal signal transmission unit 15. The first control unit 11 controls the entire biometric information acquisition device 10. The first control unit 11 is mainly composed of, for example, a CPU (not shown), a microcomputer having a storage area such as a ROM, a RAM, and a rewritable flash memory. The first communication unit 12, the position information acquisition unit 13, and the biometric information acquisition unit 14 are electrically connected to the first control unit 11, respectively. Electric power required for the operation of the biometric information acquisition apparatus 10 is supplied from a battery (not shown) built in the biometric information acquisition apparatus 10.

The first communication unit 12 is configured to be connectable to the telecommunication line 2 by a wireless communication function using, for example, a mobile phone line or a wireless LAN. The biometric information acquisition device 10 is configured to be able to mutually communicate with the monitoring device 30 and the mobile robot 20 by being connected to the electric communication line 2 by the first communication unit 12. The position information acquisition unit 13 has a function of acquiring the current position of the biometric information acquisition device 10 using, for example, a GPS (Global Positioning System) or a short-range wireless system.

The biometric information acquisition unit 14 has a function of acquiring biometric information of the monitoring target person wearing the biometric information acquisition device 10. In the present embodiment, the biological information is information relating to the life of the monitoring target person and includes at least one of pulse rate, heart rate, brain wave, cardiac potential, and body temperature.

In the case of the present embodiment, the biological information acquisition device 10 is, for example, a wristwatch type, and can acquire the pulse rate of the monitoring target person. That is, in the present embodiment, the biometric information acquisition unit 14 is a pulse sensor built in the wristwatch-type biometric information acquisition apparatus 10. In this case, the biological information acquisition unit 14 includes, for example, a light emitting element that emits light from the skin surface of the arm toward the artery and a light receiving element that receives the light reflected by the artery and changed by the pulsation of blood flowing through the artery. It is configured. Then, the biological information acquisition unit 14 can measure the pulsation rate, that is, the heart rate by detecting the change in the received light.

When the biometric information acquired by the biometric information acquisition unit 14 is out of the preset normal range, the abnormal signal transmission unit 15 directs the external device such as the monitoring device 30 via the first communication unit 12. It has the function of transmitting an abnormal signal. The normal range of the biometric information is individually set for each monitoring target person who wears the biometric information acquisition device 10. Then, each biometric information acquisition device 10 stores the normal range of the biometric information of the monitoring target person wearing the biometric information acquisition device 10 in a storage area (not shown) of the first control unit 11. In the case of the present embodiment, the biometric information acquisition device 10 stores the upper limit and the lower limit of the pulse of the monitoring target person as the normal range of the biometric information.

The storage area (not shown) of the first control unit 11 stores a program for applying the biometric information acquisition device 10 to the monitoring system 1. Then, the first control unit 11 virtually realizes the abnormal signal transmission unit 15 by software by executing the above program in a CPU (not shown). The abnormality signal transmission unit 15 may be implemented by hardware, for example, as an integrated circuit integrated with the first control unit 11.

[Mobile Robot]
The mobile robot 20 is a robot that can operate autonomously, such as patrolling around a facility or residence to be monitored. The mobile robot 20 is a robot that can be operated by remote operation from the monitoring device 30 or the like as needed. The mobile robot 20 has a second control unit 21, a second communication unit 22, a moving mechanism unit 23, a camera 24, a speaker 25, a microphone 26, and a robot side transceiver unit 27. The second controller 21 controls the entire mobile robot 20. The second controller 21 is mainly composed of, for example, a CPU (not shown), a microcomputer having a storage area such as a ROM, a RAM, and a rewritable flash memory. A storage area (not shown) of the second control unit 21 stores a program for applying the mobile robot 20 to the monitoring system 1.

The second communication unit 22, the moving mechanism unit 23, the camera 24, the speaker 25, the microphone 26, and the robot side transmitter/receiver unit 27 are electrically connected to the second control unit 21. The second communication unit 22 is configured to be connectable to the telecommunication line 2 by, for example, a wireless communication function using a telephone line or a wireless LAN. The moving mechanism unit 23 has a function of autonomously moving the mobile robot 20 in a specific area, for example, in a facility or a residence to be monitored. In this case, the mobile robot 20 can autonomously move within the area to be monitored, for example, as follows.

That is, for example, an electric or magnetic rail is provided in advance in a specific area to be monitored. And the 2nd control part 21 operates the moving mechanism part 23 so that it may move along the rail. Further, the mobile robot 20 may be configured as follows. That is, for example, marks that replace rails are provided on the ceiling, walls, floor, and the like. Then, the second control unit 21 recognizes the mark based on the image acquired by the camera 24, and operates the moving mechanism unit 23 so as to move along the mark. Furthermore, the mobile robot 20 may be configured as follows. That is, for example, the storage area of the second control unit 21 stores the map information of a specific area to be monitored, that is, the floor map of the facility or residence. And the 2nd control part 21 operates the moving mechanism part 23 so that it may move based on the map information. The moving mechanism unit 23 is not limited to one having wheels and the like to travel, and may be, for example, a flying body capable of autonomous flight.

The camera 24 has a function of photographing the periphery of the moving mechanism unit 23, that is, the periphery of the mobile robot 20. In this case, the image that can be captured by the camera 24 may be either a still image or a moving image. The speaker 25 has a function of emitting a sound to the surroundings of the mobile robot 20. The speaker 25 can emit a voice generated inside the mobile robot 20 or a voice based on voice data received from an external device such as the monitoring device 30 via the electric communication line 2. The microphone 26 can collect sound around the moving mechanism unit 23, that is, around the mobile robot 20. The voice collected by the microphone 26 is converted into voice data and transmitted to the external device, for example, the monitoring device 30 via the telecommunication line 2.

The robot-side transmitting/receiving unit 27 has a function capable of directly wirelessly communicating with an external device, for example, the sliding door opening/closing device 40, not via the electric communication line 2. In the present embodiment, the robot side transmitting/receiving unit 27 has a so-called infrared communication function capable of wireless communication by transmitting/receiving an infrared signal, for example. In addition to the functions described above, the mobile robot 20 has an acceleration sensor capable of measuring the temperature, humidity, and illuminance around the mobile robot 20, as well as the impact applied to the mobile robot 20, and the presence of people around it. You may have a human sensor etc. which can detect. Further, the mobile robot 20 has a built-in battery for supplying electric power required for the operation of the mobile robot 20.

[Monitoring device]
The monitoring device 30 presents various information acquired by the biometric information acquisition device 10 and the mobile robot 20 to the monitor, and when an abnormal signal is received from the biometric information acquisition device 10, the monitoring device 30 notifies the mobile robot 20 of the abnormal signal. Has a function of instructing to move toward the biological information acquisition apparatus 10 from which Usually, the monitoring device 30 is installed at a position away from the living room of the monitored person, that is, at a position away from the area where the monitored person exists. In this case, the monitoring device 30 may be installed in the same building as the building having the room of the monitoring target person, or may be installed in a different building.

The monitoring device 30 includes a third control unit 31, a third communication unit 32, a monitor 33, a speaker 34, and a microphone 35. The monitoring device 30 may be a computer dedicated to the monitoring system 1, or may be, for example, a general-purpose personal computer or a so-called smart phone or a highly functional mobile terminal such as a tablet terminal. The third control unit 31 controls the entire monitoring device 30. The third control unit 31 is mainly composed of, for example, a CPU (not shown), a microcomputer having a storage area such as a ROM, a RAM, and a rewritable flash memory. A storage area (not shown) of the third control unit 31 stores a program for applying the monitoring device 30 to the monitoring system 1.

The third communication unit 32, the monitor 33, the speaker 34, and the microphone 35 are electrically connected to the third control unit 31, respectively. The third communication unit 32 is configured to be connectable to the telecommunication line 2 by a communication function using a telephone line, a wired or wireless LAN, or the like. The monitor 33 is, for example, a general liquid crystal monitor or the like, and displays biometric information acquired from the biometric information acquisition device 10 via the electric communication line 2 or an image or video image captured by the camera 24 of the mobile robot 20. It has a function.

The speaker 34 has a function of emitting a sound to the surroundings of the monitoring device 30. The speaker 34 can emit a voice generated inside the monitoring device 30 and a voice based on voice data received from an external device such as the mobile robot 20 via the electric communication line 2. The microphone 35 can collect the sound around the monitoring device 30. The voice collected by the microphone 35 is converted into voice data and transmitted to an external device such as the mobile robot 20 via the electric communication line 2. That is, when the monitoring target person is present in front of the camera 24 of the mobile robot 20, the monitoring person who handles the monitoring device 30 looks at the monitoring target person displayed on the monitor 33 and looks at the speakers 25 and 34 and the microphone 26. Through 35, a conversation can be conducted with the monitored person.

[Sliding door opening/closing device]
As shown in FIG. 2, the sliding door opening/closing device 40 is attached to a sliding door 91 provided at a doorway of a living room or the like. In FIG. 2, the direction perpendicular to the paper surface is the opening/closing direction of the sliding door 91. In response to an instruction from the mobile robot 20 or the monitoring device 30, the sliding door opening/closing device 40 can switch the sliding door 91 in the living room between an automatic door state that can be automatically opened and closed and a manual door state that can be manually opened and closed. In the case of the present embodiment, the sliding door opening/closing device 40 switches the sliding door 91 between the automatic door state and the manual door state according to an instruction from the mobile robot 20 by directly communicating with the mobile robot 20.

In the present embodiment, the automatic door state is a state in which the sliding door 91 can be automatically opened and closed by the action of the sliding door opening/closing device 40 without a person touching the sliding door 91, that is, without the force of a person acting on the sliding door 91. Say. Further, the manual door state is a state in which a person can touch the sliding door 91 and apply the force of the person to manually open and close the sliding door 91. In this case, the concept of the automatic door state may include a state in which a person can apply a large force to the sliding door 91 to forcibly open and close it. That is, when a person manually opens and closes the sliding door 91, the force required to open and close the sliding door 91 in the manual door state is smaller than the force required to open and close the sliding door 91 in the automatic door state. That is, when the sliding door 91 is in the manual door state, a person can open and close the sliding door 91 with a smaller force than when the sliding door 91 is in the automatic door state.

In the present embodiment, the sliding door opening/closing device 40 is provided at a position visible from the outside of the sliding door 91 by being attached to the sliding door 91 afterwards. That is, the sliding door opening/closing device 40 of the present embodiment is not installed in advance in the sliding door 91, but can be attached afterwards to the sliding door 91 which is already configured as a manual door state. Note that the sliding door opening/closing device 40 may not be attached to the sliding door 91 afterwards, but may be incorporated in the sliding door 91 in advance.

The sliding door 91 to which the sliding door opening/closing device 40 is attached is preferably a hanging sliding door as shown in FIG. In the case of the present embodiment, the sliding door 91 is suspended on a rail 94 provided on the ceiling 92 or the upper wall 93, and opens and closes along the rail 94. This is because the hanging sliding door 91 requires less force to open and close than a sliding door that is not hanging, that is, a sliding door that opens and closes along a rail installed on the floor 95. Thereby, the output of the sliding door opening/closing device 40 can be reduced, and as a result, the size and power consumption of the sliding door opening/closing device 40 can be suppressed. However, the sliding door 91 to which the sliding door opening/closing device 40 is attached does not necessarily have to be a hanging type.

As shown in FIGS. 1 and 2, the sliding door opening/closing device 40 includes a fourth control unit 41, a sliding door side transmitting/receiving unit 42, a motor 43, an opening/closing detection unit 44, and a switching mechanism unit 45. Further, the sliding door opening/closing device 40 has a rack gear 46 and a pinion gear 47, as shown in FIG. The rack gear 46 and the pinion gear 47 are configured so that they can be fitted to each other. The rack gear 46 is provided in the sliding door 91 along the opening/closing direction of the sliding door 91 so that the longitudinal direction of the rack gear 46 faces the opening/closing direction of the sliding door 91, as shown in FIGS.

In this case, the rack gear 46 among the components of the sliding door opening/closing device 40 is provided above the sliding door 91. On the other hand, among the components of the sliding door opening/closing device 40, the components other than the rack gear 46, that is, the fourth control unit 41, the sliding door side transmitting/receiving unit 42, the motor 43, the opening/closing detection unit 44, and the switching mechanism unit 45 are located above the sliding door 91. It is provided on the ceiling 92 or the wall surface of the wall 93. In this case, the sliding door opening/closing device 40 is connected to an outlet in the living room, and the power required for the operation of the sliding door opening/closing device 40 is supplied from, for example, the outlet in the living room.

The pinion gear 47 is provided on the rotation shaft of the motor 43. When the motor 43 is operated with the rack gear 46 and the pinion gear 47 fitted to each other, the rotation of the motor 43 is transmitted to the rack gear 46 via the pinion gear 47. As a result, the sliding door 91 is automatically opened and closed according to the rotation direction of the motor 43.

The fourth control unit 41 controls the entire sliding door opening/closing device 40. The fourth control unit 41 is mainly composed of, for example, a CPU (not shown), a microcomputer having a storage area such as a ROM, a RAM, and a rewritable flash memory. The sliding door side transmitter/receiver 42, the motor 43, the opening/closing detector 44, and the switching mechanism 45 are each electrically connected to the fourth controller 41.

The sliding door transmission/reception unit 42 has a function of directly communicating with an external device, for example, the mobile robot 20, without going through the electric communication line 2. In the case of the present embodiment, the sliding door side transmitting/receiving unit 42 has a so-called infrared communication function capable of wireless communication by transmitting/receiving an infrared signal, for example. The sliding door transmitter/receiver 42 is provided outside the living room, that is, on the corridor side. The sliding door-side transmitting/receiving unit 42 is connected to the fourth control unit 41 provided on the living room side by electrical wiring passed through the wall 93. In this case, the robot side transmitter/receiver 27 and the sliding door side transmitter/receiver 42 cannot communicate with each other with the wall 93 in between, so that the mobile robot 20 can be communicated with each other only when the mobile robot 20 is on the corridor side. Communication becomes possible.

The robot-side transceiver unit 27 and the sliding-door-side transceiver unit 42 are not limited to the infrared communication function, and may have a function such as near field communication (NFC: Near Field Communication) using an electric wave or a magnetic field. Good. Also in this case, since the robot side transmitter/receiver 27 and the sliding door side transmitter/receiver 42 cannot communicate with each other with the wall 93 separated, only when the mobile robot 20 is present in the corridor side, It becomes possible to communicate with each other.

Further, the robot side transmitter/receiver 27 and the sliding door side transmitter/receiver 42 are not limited to those described above, and may communicate with each other by, for example, a wireless LAN. In this case, the robot-side transmitter/receiver 27 and the sliding door-side transmitter/receiver 42 can communicate with each other with the wall 93 in between, so that the mobile robot 20 is not limited to the case where the mobile robot 20 is present in the corridor, and is not limited to the room side. Even if they exist, they can communicate with each other. Therefore, in this case, the sliding door side transmitting/receiving unit 42 may be provided inside the living room. Further, the sliding door opening/closing device 40 can communicate with an external device such as the mobile robot 20 or the monitoring device 30 via the electric communication line 2 in place of the sliding door side transmitting/receiving unit 42 or in addition to the sliding door side transmitting/receiving unit 42. You may have a part.

The open/close detection unit 44 has a function of detecting the open state and the closed state of the sliding door 91. The open/close detection unit 44 virtually detects the open/closed state of the sliding door 91 by measuring the number of rotations of the motor 43, for example. The open/close detection unit 44 may be configured by a proximity sensor or a mechanical switch provided on the sliding door 91 or the rack gear 46, and may directly detect the open/closed state of the sliding door 91.

The switching mechanism unit 45 is a drive mechanism such as an electric cylinder or a solenoid actuator. The motor 43 is provided in the switching mechanism unit 45. Accordingly, the switching mechanism unit 45 can move the pinion gear 47 together with the motor 43. The switching mechanism unit 45 moves the motor 43 in the horizontal direction, that is, the left-right direction in FIG. 2, so that the rack gear 46 and the pinion gear 47 are in a fitted state and the rack gear 46 and the pinion gear 47 are in a fitted state. It is possible to switch between the non-fitted state in which is released.

In the fitted state where the rack gear 46 and the pinion gear 47 are fitted, the rotation of the motor 43 can be transmitted to the rack gear 46 via the pinion gear 47. Therefore, in this fitted state, the sliding door 91 is in an automatic door state in which it is automatically opened and closed by the action of the sliding door opening/closing device 40, that is, the action of the motor 43. On the other hand, the rotation of the motor 43 is not transmitted to the rack gear 46 in the non-fitted state where the fitting between the rack gear 46 and the pinion gear 47 is released. In this case, the rotation resistance force generated when the rotation shaft of the motor 43 is rotated by the external force is not transmitted to the rack gear 46. Therefore, in this non-fitting state, the sliding door 91 is in a manual door state that can be opened and closed with a smaller force than in the automatic door state.

[Control and operation contents of each device]
Next, with reference to FIGS. 3 to 15, the control and operation contents of the respective devices 10, 20, 30, 40 will be described. Each device 10, 20, 30, 40 operates by the CPU of each control unit 11, 21, 31, 41 executing a program stored in the storage area of each control unit 11, 21, 31, 41. .. In the following description, the subject that performs control will be described as the control units 11, 21, 31, 41.

[Control and operation contents of biometric information acquisition device]
First, an example of control and operation contents performed by the biometric information acquisition device 10 will be described with reference to FIG. In the case of the present embodiment, the biometric information acquisition device 10 sets the monitoring target to have a normal state, that is, when the biometric information acquired by the biometric information acquisition unit 14 is within the normal range, for example, every one minute. To get biometric information. On the other hand, when an abnormality occurs in the person to be monitored, that is, when the acquired biometric information is out of the normal range, an abnormal signal is transmitted to the monitoring device 30 and the biometric information is constantly acquired. According to this, the operating time of the biometric information acquisition unit 14 can be reduced in a normal time when no abnormality occurs, and thus power consumption can be suppressed. The biometric information acquisition device 10 may be configured to constantly acquire biometric information regardless of whether or not an abnormality has occurred.

Specifically, as shown in FIG. 3, when the first control unit 11 of the biometric information acquisition device 10 starts control (start), the biometric information acquisition unit 14 is operated in step S11 to operate the biometric information of the monitoring target person. Get information. Next, in step S12, the first control unit 11 determines whether or not an abnormal signal is being transmitted. When the abnormal signal is being transmitted (YES in step S12), the first control unit 11 shifts the processing to step S16.

On the other hand, when the abnormal signal is not being transmitted (NO in step S12), the first control unit 11 determines in step S13 whether the value of the biometric information acquired in step S11 is within the normal range. Then, if the value of the biometric information is within the normal range (YES in step S13), the first control unit 11 waits for a predetermined period, for example, 1 minute in step S14 (NO in step S14), and the predetermined period elapses. After that (YES in step S14), the process returns to step S11 to repeat the processes of step S11 and subsequent steps.

When the value of the biometric information is out of the normal range (NO in step S13), the first control unit 11 determines that the monitoring target person has an abnormality. Then, the first control unit 11 shifts the processing to step S15 and operates the abnormal signal transmitting unit 15 to transmit the abnormal signal. Then, the 1st control part 11 operates the position information acquisition part 13 in step S16, and acquires the position of the biometric information acquisition device 10, ie, the position of a monitoring subject. Then, in step S17, the first control unit 11 operates the first communication unit 12 to transmit the abnormality signal and various information such as position information and biometric information to the monitoring device 30. The abnormality signal and various information may be transmitted to the mobile robot 20 in addition to the monitoring device 30.

Next, the 1st control part 11 judges whether the cancellation signal was received in step S18. The cancellation signal is a signal for stopping the abnormal signal transmitted in step S15, and is transmitted from the monitoring device 30 in the case of the present embodiment. When the release signal is received (YES in step S18), the first control unit 11 shifts the processing to step S19 and stops the abnormal signal transmitted in step S15. On the other hand, when the cancellation signal is not received (NO in step S18), the first control unit 11 continues to transmit the abnormal signal. After that, the first control unit 11 shifts the processing to step S11 and repeats the processing from step S11.

[Control and operation contents of monitoring device]
Next, an example of control and operation contents performed by the monitoring device 30 will be described with reference to FIG. In the case of the present embodiment, the video captured by the camera 24 of the mobile robot 20 is displayed on the monitor 33 of the monitoring device 30. When an abnormal signal is received from the biometric information acquisition apparatus 10, the speaker 25 notifies that fact, and the monitor 33 displays the biometric information and the positional information received from the biometric information acquisition apparatus 10 that has transmitted the abnormal signal. It

Specifically, as shown in FIG. 4, when the control is started (start), the third control unit 31 of the monitoring device 30 operates the monitor 33 in step S21 to take an image with the camera 24 of the mobile robot 20. Display the image. Next, the 3rd control part 31 judges whether the abnormal signal is received from the biometric information acquisition apparatus 10 in step S22. When the abnormal signal is not received (NO in step S22), the third control unit 31 shifts the processing to step S21 and repeats steps S21 and S22. On the other hand, when the abnormal signal is received (YES in step S22), the third control unit 31 shifts the processing to step S23.

In step S23, the third control unit 31 operates the speaker 25 to notify that the abnormal signal has been received, that is, the monitored person is informed that an abnormality has occurred. Further, in step S24, the third control unit 31 causes the monitor 33 to display various information such as biometric information and position information received from the biometric information acquisition apparatus 10 that has transmitted the abnormal signal. In this case, various kinds of information are displayed on the monitor 33 together with the image captured by the camera 24.

Next, in step S25, the third control unit 31 determines whether or not a movement command has been transmitted to the mobile robot 20. The movement command is generated based on the position information acquired from the biometric information acquisition device 10, and is a command signal for moving the mobile robot 20 toward the biometric information acquisition device 10 that has transmitted the abnormal signal. is there. This movement command includes position information of the biometric information acquisition device 10, that is, destination information of the mobile robot 20.

When the movement command is not yet transmitted (NO in step S25), the third control unit 31 shifts the processing to step S26, generates the movement command, and transmits the movement command to the mobile robot 20. After that, the third control unit 31 shifts the processing to step S27. If the movement command has already been transmitted (YES in step S25), the third control unit 31 shifts the processing to step S27 without executing step S26.

After that, the third control unit 31 determines whether or not there is an abnormality cancellation input in step S27. The abnormality cancellation input is, for example, an input operation performed by an observer on an operation unit (not shown). The input operation for canceling the abnormality is performed, for example, when the monitoring person confirms the state of the monitoring target person. In this case, the operation unit (not shown) used for the input operation for canceling the abnormality may be provided in any of the biological information acquisition device 10, the mobile robot 20, or the monitoring device 30. By providing the biological information acquisition device 10 with an operation unit used for an input operation for canceling the abnormality, the observer wears the biological information acquisition device 10 when performing the input operation for canceling the abnormality. People will be directly touched, and as a result, the reliability of monitoring will be improved.

When an abnormality cancellation input is made (YES in step S27), the third control unit 31 transmits a cancellation signal to the biological information acquisition device 10 and the mobile robot 20 that transmitted the abnormality signal in step S28. Then, the 3rd control part 31 returns to step S21, and repeats the process after step S21. On the other hand, if there is no input for canceling the abnormality (YES in step S27), the third control unit 31 returns to step S21 and repeats the processing of step S21 and thereafter without executing step S28.

[Control and operation contents of mobile robot]
Next, an example of control and operation contents performed by the mobile robot 20 will be described with reference to FIGS. In the case of the present embodiment, the mobile robot 20 patrols a preset route when there is no abnormality in the monitored person, that is, when no abnormality signal is received from the biological information acquisition device 10 or the monitoring device 30, Evenly monitor the area to be monitored. On the other hand, when an abnormality occurs in the monitoring target person, that is, when the mobile robot 20 receives an abnormal signal from the biological information acquisition apparatus 10 or the monitoring apparatus 30, the mobile robot 20 outputs the abnormal signal of the biological information acquisition apparatus 10. Move from the current location as the destination. Thereby, the mobile robot 20 focuses on the wearer of the biometric information acquisition device 10, that is, the monitoring target person in which the abnormality has occurred.

Specifically, as shown in FIG. 5, when the second control unit 21 of the mobile robot 20 starts the control (start), the moving mechanism unit 23 is operated in step S31 to perform the patrol operation, and the step is performed. In step S32, the camera 24 is operated to capture the surrounding image. Next, the 2nd control part 21 judges whether the abnormal signal was received from the biometric information acquisition apparatus 10 or the monitoring apparatus 30 in step S33. When the abnormality signal has not been received (NO in step S33), the second control unit 21 determines that no abnormality has occurred in the monitored person, and repeats the processing of steps S31 and S32. On the other hand, when the abnormality signal is received (YES in step S33), the second control unit 21 determines that the monitoring target person has an abnormality, and moves the process to step S34.

In step S34, the second control unit 21 determines whether or not the movement command is received from the monitoring device 30, and when the movement command is not received (NO in step S34), waits until the movement command is received. To do. Then, when the second control unit 21 receives the movement command from the monitoring device 30 (YES in step S34), the process proceeds to step S35, the movement mechanism unit 23 is operated, and the movement is started.

When the mobile robot 20 enters the monitored person's room, as shown in FIG. 9, the mobile robot 20 temporarily stops at a position a predetermined distance L before the sliding door 91. Then, the second control unit 21 executes the entry process in step S36 of FIG. When the room entry process is executed, the second control unit 21 operates the robot side transceiver unit 27 in step S361 of FIG. The entry request signal is a signal transmitted when the mobile robot 20 requests entry, and is a signal that triggers the sliding door opening/closing device 40 to automatically open the sliding door 91. When the sliding door 91 is opened by the sliding door opening/closing device 40 and the mobile robot 20 is allowed to enter the living room, the sliding door opening/closing device 40 transmits an entry permission signal.

In step S362, the second control unit 21 determines whether or not the entry permission signal from the sliding door opening/closing device 40 has been received. If the entry permission signal has not been received (NO in step S362), the second control unit 21 repeats steps S362 and 363 until the predetermined time has elapsed in step S363, and waits for the entry permission signal. Then, when the predetermined time has elapsed without receiving the entry permission signal (YES in step S363), the second control unit 21 operates the second communication unit 22 to enter the monitoring device 30 in the step S364. After transmitting the failure signal, the operator waits for the returning operation. On the other hand, when the second control unit 21 receives the entry permission signal (YES in step S362), the process proceeds to step S365 and the moving mechanism unit 23 is operated to enter the living room as shown in FIG. .. After that, the second control unit 21 shifts the processing to step S37 of FIG. 5 (return).

The sliding door opening/closing device 40 maintains the sliding door 91 in an open state while the mobile robot 20 is in the living room. In step S37, the second control unit 21 determines whether or not the release signal is received from the biological information acquisition device 10 or the monitoring device 30, and waits on the spot until the release signal is received (NO in step S37). .. Then, when the release signal is received (YES in step S37), the second control unit 21 shifts the processing to step S38, and executes the leaving processing.

When the leaving process is executed, the second control unit 21 operates the moving mechanism unit 23 in step S381 of FIG. 7 to cause the mobile robot 20 to leave the room as shown in FIG. The second control unit 21 controls the moving mechanism unit 23 in step S382 to temporarily stop the mobile robot 20 at a position before the sliding door 91 by a predetermined distance L, as shown in FIG. After that, the second control unit 21 operates the robot side transmitting/receiving unit 27 in step S383 of FIG. 7, and transmits a leaving completion signal to the sliding door side transmitting/receiving unit 42 of the sliding door opening/closing device 40. The leaving-completion signal is a signal transmitted when the mobile robot 20 completes leaving the room, and is a signal that serves as a trigger for the sliding door opening/closing device 40 to automatically close the sliding door 91. When the sliding door 91 is closed by the sliding door opening/closing device 40, a closing completion signal indicating that the closing of the sliding door 91 is completed is transmitted from the sliding door side transmitter/receiver 42 of the sliding door opening/closing device 40.

Then, the 2nd control part 21 judges whether the closing completion signal was received from the sliding door opening/closing apparatus 40 in step S384. When the closing completion signal is received (YES in step S384), the second control unit 21 proceeds to step S31 in FIG. 5 and restarts the patrol operation. On the other hand, when the closing completion signal has not been received (NO in step S384 in FIG. 7), the second control unit 21 repeats steps S384 and 385 until the predetermined time elapses, and waits for reception of the closing completion signal. Then, when the predetermined period of time has passed without receiving the closing completion signal (YES in step S385), the second control unit 21 operates the second communication unit 22 in step 386 to cause the monitoring device 30 to operate. , And transmits a closing failure signal indicating that closing of the sliding door 91 has failed. Then, the second control unit 21 proceeds to step S31 of FIG. 5 and restarts the patrol operation.

[Control and operation of sliding door opening/closing device]
Next, an example of control and operation contents performed by the sliding door opening/closing device 40 will be described with reference to FIGS. 8 to 15. The white arrows in FIGS. 10 to 15 indicate the movement or drive direction of each element. Further, “front” and “rear” in FIGS. 9 to 15 indicate “front” and “rear” of the mobile robot 20, respectively. In the following description, the rotation direction of the motor 43 when opening the sliding door 91 is forward rotation, and the rotation direction of the motor 43 when closing the sliding door 91 is reverse rotation.

In the case of the present embodiment, the sliding door opening/closing device 40 maintains the sliding door 91 in the manual door state until receiving the entry request signal from the mobile robot 20. When the sliding door opening/closing device 40 receives the entry request signal from the mobile robot 20, the sliding door opening/closing device 40 maintains the sliding door 91 in the automatic door state until the closing of the sliding door 91 is completed and the closing completion signal is transmitted.

Specifically, as shown in FIG. 8, when the control starts (start), the fourth control unit 41 of the sliding door opening/closing device 40 operates the sliding door side transmitting/receiving unit 42 in step S41 to enter the room from the mobile robot 20. It is determined whether the request signal is received. When the entry request signal is not received (NO in step S41), the fourth control unit 41 waits while keeping the sliding door 91 in the manual door state. On the other hand, when the fourth control unit 41 receives the entry request signal (YES in step S41), the fourth control unit 41 operates the switching mechanism unit 45 to execute the switching operation in step S42. In this case, as shown in FIG. 10, the switching mechanism unit 45 causes the motor 43 to move to the rack gear 46 side so that the pinion gear 47 and the rack gear 46 are fitted to each other, whereby the sliding door 91 is changed from the manual door state to the automatic door state. Switch to.

After that, the fourth control unit 41 causes the motor 43 to rotate forward in step S43 of FIG. Thereby, as shown in FIG. 11, the sliding door 91 is automatically opened. The fourth controller 41 continues driving the motor 43 until the opening/closing detector 44 detects that the sliding door 91 is opened (NO in step S44 of FIG. 8 ). When the opening/closing detector 44 detects that the sliding door 91 has been opened (YES in step S44), the fourth controller 41 stops the motor 43 in step S45. Thereafter, as shown in FIG. 11, the fourth control unit 41 operates the sliding door side transmission/reception unit 42 to transmit a room entry permission signal to the mobile robot 20. Then, the mobile robot 20, which has received the entry permission signal, enters the living room, as shown in FIG.

After that, the fourth control unit 41 determines whether or not the leaving completion signal is received from the mobile robot 20 in step S47 of FIG. The fourth controller 41 waits until it receives the leaving completion signal (NO in step S47). Then, when the fourth control unit 41 receives the leaving completion signal from the mobile robot 20 as shown in FIG. 13 (YES in step S47 of FIG. 8), the motor 43 is reversely rotated in step S48 to close the sliding door 91. The fourth control unit 41 continues driving the motor 43 until the opening/closing detection unit 44 detects that the sliding door 91 is closed (NO in step S49).

When the opening/closing detector 44 detects that the sliding door 91 is closed (YES in step S49), the fourth controller 41 stops the motor 43 in step S50. Then, the 4th control part 41 operates the switching mechanism part 45 in step S51, and performs a switching operation. In this case, as shown in FIG. 15, the switching mechanism unit 45 moves the motor 43 in a direction away from the rack gear 46 to release the fitting between the pinion gear 47 and the rack gear 46, thereby automatically moving the sliding door 91. Switch from the door state to the manual door state. Then, the fourth control unit 41 operates the sliding door side transmitting/receiving unit 42 in step S52 of FIG. 8 to transmit a closing completion signal toward the mobile robot 20 side as shown in FIG. After that, the fourth control unit 41 returns the processing to step S41 in FIG. 8 and repeats the processing from step S41.

According to the embodiment described above, the monitoring system 1 determines an abnormality based on the biometric information of the monitoring target person acquired by the biometric information acquisition device 10. Therefore, it is possible to directly detect the abnormal state of the monitoring target person. Then, when an abnormality occurs in the monitoring target person who wears the biological information acquisition device 10, the mobile robot 20 moves toward the monitoring target person in which the abnormality has occurred. Thereby, the monitor person can quickly confirm the abnormal state of the monitor target person by looking at the monitor 33 of the monitoring device 30 even in a remote place away from the monitor target person.

The monitoring system 1 includes a plurality of biological information acquisition devices 10. Then, the plurality of biological information acquisition devices 10 are attached to different monitoring subjects. That is, the monitoring system 1 can monitor a plurality of monitored persons with one monitoring device 30. According to this, even when it is necessary to monitor a large number of people to be monitored, such as a hospital or a nursing facility, a small number of people can deal with it, and as a result, monitoring is required. The number of personnel can be reduced.

Here, in order to move the mobile robot 20 into and out of the living room, it is necessary to open and close the sliding door 91. In this case, for example, the sliding door 91 may be a general automatic door, or the mobile robot 20 may be provided with an arm for opening and closing the sliding door 91. However, if the sliding door 91 is an automatic door, for example, the sliding door 91 opens and closes every time a person passes in front of the sliding door 91. Therefore, making it an automatic door is not suitable as a sliding door 91 for a living room. Further, if the mobile robot 20 is provided with an arm for opening and closing the sliding door 91, the configuration and control of the mobile robot 20 becomes complicated, and the cost of the mobile robot 20 also increases.

Therefore, in the present embodiment, the monitoring system 1 further includes the sliding door opening/closing device 40. In response to an instruction from the mobile robot 20 or the monitoring device 30, the sliding door opening/closing device 40 switches the sliding door 91 in the living room between an automatic door state in which it can be automatically opened and closed and a manual door state in which it can be opened and closed manually. According to this, when the mobile robot 20 enters and leaves the sliding door 91, the sliding door 91 can be in the automatic door state, and in other cases, the sliding door 91 can be in the manual door state. Therefore, the monitoring system 1 can avoid the above-described inconvenience that may occur when the sliding door 91 is a general automatic door or the mobile robot 20 is provided with an arm for opening and closing the sliding door 91, and the like. The advantages of both the automatic door state and the manual door state can be obtained.

The mobile robot 20 and the sliding door opening/closing device 40 have transmitting/receiving units 27 and 42 capable of wirelessly communicating with each other by transmitting/receiving infrared signals. According to this, as compared with the mobile robot 20 and the sliding door opening/closing device 40 that use radio waves for communication, the configuration can be relatively inexpensive. Furthermore, in the case of wireless communication using radio waves, the mobile robot 20 must always maintain a communication state with all the sliding door opening/closing devices 40. Therefore, the radio wave band is wasted and power consumption is large. Become. However, as in this embodiment, by enabling one-to-one communication by infrared communication, it is possible to reduce the power consumption without wasting the radio band. This is more effective when the number of sliding door opening/closing devices 40 increases, that is, when the number of persons to be monitored increases.

The sliding door opening/closing device 40 is provided at a position visible from the outside of the sliding door 91. That is, in the case of the present embodiment, the sliding door opening/closing device 40 is not installed in advance inside the sliding door 91, but can be attached from outside the sliding door 91. That is, the sliding door opening/closing device 40 of the present embodiment can be attached afterwards to the sliding door 91 that was originally dedicated to manual operation. According to this, even if the facility which has the manual sliding door 91 is not supposed to be applied at the beginning and the sliding door opening/closing device 40 is attached to the sliding door 91, the sliding door 91 Can be applied to the monitoring system 1. Moreover, according to this, since it becomes easy to remove the sliding door opening/closing device 40, it becomes easy to perform maintenance of the sliding door opening/closing device 40 and to return the sliding door 91 to the manual only.

The sliding door opening/closing device 40 includes a sliding door side transmitting/receiving unit 42, a rack gear 46, a pinion gear 47, a motor 43, and a switching mechanism unit 45. In this case, the sliding door transmission/reception unit 42 functions, for example, as a reception unit that can receive a signal from an external device, that is, the mobile robot 20. Then, the switching mechanism unit 45 moves the motor 43 based on the signal received by the sliding door side transmitting/receiving unit 42 to switch the fitting state of the rack gear 46 and the pinion gear 47, thereby making the sliding door 91 in the automatic door state and the manual state. Switch to the door state. According to this, the sliding door opening/closing device 40 can have a relatively simple configuration.

It should be noted that the embodiment of the present invention is not limited to the embodiments described above and illustrated in the drawings, and can be appropriately modified without departing from the scope of the invention.

In the drawings, 1 is a monitoring system, 2 is an electric communication line, 10 is a biometric information acquisition device, 12 is a first communication unit, 14 is a biometric information acquisition unit, 15 is an abnormal signal transmission unit, 20 is a mobile robot, and 22 is a second. 2 communication unit, 23 is a moving mechanism unit, 24 is a camera, 30 is a monitoring device, 32 is a third communication unit, 33 is a monitor, 40 is a sliding door opening/closing device, 42 is a sliding door side transmitting/receiving unit (transmission/reception unit, receiving unit), 43 is a motor, 45 is a switching mechanism, 46 is a rack gear, and 47 is a pinion gear.

Claims (4)

A biometric information acquisition unit that can acquire the biometric information of the person to be monitored, a first communication unit that can communicate through an electric communication line, and an abnormality that sends an abnormal signal when the biometric information deviates from a preset normal range. A signal transmitting unit, and a biometric information acquisition device wearable on the monitoring target,
A mobile robot having a second communication unit capable of communicating through the electric communication line and a moving mechanism unit capable of autonomously moving within a specific area;
A monitoring device having a third communication unit capable of communicating through the electric communication line;
An automatic door attached to a sliding door in the living room of the person to be monitored, configured to be able to directly communicate with the mobile robot without going through the electric communication line, and capable of automatically opening and closing the sliding door according to an instruction from the mobile robot. Equipped with a sliding door opening and closing device that can be switched between a state and a manual door state that can be opened and closed manually,
When the mobile robot receives the abnormal signal, the mobile robot moves toward the biological information acquisition device to which the abnormal signal is transmitted, and when the mobile robot enters the room of the monitored person, the front side of the sliding door. At the position of 1, and communicates directly with the sliding door opening/closing device to switch the sliding door opening/closing device to the automatic door state, open the sliding door, and enter the living room, the biological information acquisition device or the mobile robot. Alternatively, when an operation for canceling an abnormality is input to any of the monitoring devices, the user exits the room and sends a leaving completion signal when the leaving is completed,
The sliding door opening/closing device maintains the sliding door in an open state while the mobile robot is in the living room, and the mobile robot exits the living room to output a leaving completion signal transmitted from the mobile robot. Upon reception, the sliding door is closed and then the sliding door is brought into a manual state,
Monitoring system. The mobile robot and the sliding door opening/closing device each have a transmitting/receiving unit capable of wirelessly communicating with each other by transmitting/receiving a signal,
The transmitting/receiving unit of the sliding door opening/closing device is provided outside the living room,
The monitoring system according to claim 1. The sliding door opening/closing device maintains the sliding door in a manual door state until receiving a room entry request signal from the mobile robot, and when receiving the room entry request signal from the mobile robot, closing of the sliding door is completed. Maintaining the sliding door in an automatic door state until a signal is transmitted,
The monitoring system according to claim 1. The mobile robot further includes a camera capable of photographing the periphery of the moving mechanism unit,
The monitoring device further includes a monitor capable of displaying an image or video taken by the camera,
The monitoring system according to any one of claims 1 to 3.

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