JP2006115240A - Monitoring system of specific region - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily and correctly move a monitoring terminal to a desired monitoring point. <P>SOLUTION: The system comprises a monitoring terminal 1 capable of moving within a predetermined region and provided with an image pickup device 110, communication means 2, 120, a moving carriage device 11, and a control means 100; and a monitoring device 6 transmitting moving information to the monitoring terminal 1, and capable of displaying the image of the specific region to be transmitted from the monitoring terminal 1. The monitoring terminal 1 can be moved in a remote control mode by the monitoring device 6. The monitoring terminal 1 is provided with a position specifying means 100 for specifying the present position of the moving carriage device 11 on a moving route, and a monitoring point information storage means for storing the monitoring point information including a position on the moving route at that time point in response to reception of a registration request from the monitoring device 6. The control means 100 performs control to move the moving carriage device to the position of the stored monitoring point information on the basis of reception of a monitoring point moving request to be transmitted from the monitoring device 6. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a monitoring system for a specific area in which a specific area where a monitoring terminal is installed can be remotely monitored using a monitoring device such as a telephone or a personal computer owned by a user.

  In recent years, the communication network has been improved due to factors such as the increased awareness of crisis management and the awareness of self-help efforts for self-defense, and the rapid spread of computer networks such as the Internet, which has led to the establishment of a constantly connected communication environment at a low cost. A monitoring system has been put into practical use so that it can monitor the situation in a specific area, for example, at home, at a company or in a factory, even when it is necessary or anxious. .

  However, in order to closely monitor the situation in these specific areas such as homes, offices, and factories, there is a limit to the range that can be monitored by a single surveillance camera, so a plurality of surveillance cameras must be installed. There is a problem that the system cost becomes high, and as a system to solve these problems, the surveillance camera is moved on the rail and monitored, and the specific area is closely monitored with the minimum surveillance camera. A monitoring system that can be used has been proposed (see, for example, Patent Document 1).

WO 03/085983 Publication

  However, in the monitoring system of Patent Document 1, although a plurality of monitoring points can be monitored by moving the monitoring terminal, to return to the monitoring point once monitored, the monitoring terminal is moved to a desired monitoring point by operating by himself. Not only is it cumbersome, it is difficult to determine whether the position is the same as the position that was previously monitored, or how it can be moved to the desired monitoring point There was a problem that it was difficult to grasp.

  The present invention has been made paying attention to such problems, and provides a monitoring system for a specific region that can be easily monitored by accurately moving a monitoring terminal to a desired monitoring point. It is aimed.

In order to solve the above problems, a monitoring system for a specific area according to claim 1 of the present invention provides:
An imaging device for capturing an image of a specific area to be monitored; a communication means for transmitting an image captured by the imaging apparatus to a monitoring device provided outside the specific area; A monitoring terminal, comprising: a moving carriage device that moves on a moving route installed in the area; and a control unit that controls movement by the moving carriage apparatus, the moving carriage apparatus being movable within a specific area; ,
The monitoring terminal is connected so as to be capable of data communication through the communication means, transmits movement information based on a movement instruction received from a monitor to the monitoring terminal, and is imaged by the imaging device transmitted from the monitoring terminal. A monitoring device capable of receiving at least monitoring information including an image of the specific area and displaying at least an image of the specific area included in the monitoring information;
And the control means controls the movement by the mobile carriage device based on the movement information transmitted from the monitoring device, so that the specific area where the monitoring terminal is installed is In a monitoring system in a specific area that can be remotely monitored by remotely operating the movement of the monitoring terminal,
The monitoring terminal is
Position specifying means for specifying a current position on the moving route of the mobile carriage device;
Monitoring that stores monitoring point information including a position on the moving route at that time specified by the position specifying means in response to reception of a registration request transmitted based on a registration operation of a monitor in the monitoring device Point information storage means;
The control means includes a monitoring point stored in the monitoring point information storage unit based on reception of a monitoring point movement request transmitted from the monitoring device based on a predetermined operation of the monitoring person in the monitoring device. It is characterized in that a position included in the information is specified, and control is performed to move the mobile carriage device to the specified position.
According to this feature, the monitor only performs a predetermined operation for moving the monitoring terminal to the monitoring point where the registration operation has been performed in the monitoring device, and the monitoring point information stored in the monitoring point information storage means The position of the monitoring point selected by the predetermined operation is specified based on the control point and controlled by the control means so that the monitoring terminal automatically moves to the specified position. Monitoring can be carried out by accurately moving the monitoring terminal.

The specific area monitoring system according to claim 2 of the present invention is the specific area monitoring system according to claim 1,
The monitoring terminal is
A route information storage unit for storing route information capable of generating a route image of the travel route;
Route information transmitting means for transmitting the route information stored in the route information storage unit to the monitoring device;
Current position information transmitting means for transmitting current position information capable of specifying the current position specified by the position specifying means to the monitoring device;
Monitoring point information transmitting means for transmitting the monitoring point information stored in the monitoring point information storage means to the monitoring device;
With
The monitoring device is an area corresponding to a current position specified from current position information transmitted from the current position information transmission unit on a route image generated from the route information transmitted from the route information transmission unit. And the identified area can be identified as the current position of the monitoring terminal, and the area corresponding to the position included in the monitoring point information transmitted from the monitoring point information transmitting means is identified and identified. A route image that can be identified as the monitoring point registration position is generated, and the generated route image is displayed together with an image of a specific region included in the monitoring information received from the monitoring terminal.
According to this feature, the current position of the monitoring terminal is specified in the monitoring terminal, and a route image capable of specifying the current position of the specified monitoring terminal and the position of the monitoring point on which the registration operation has been performed is displayed on the monitoring device. Since the generated route image is displayed on the monitoring device together with the image of the specific area, the monitor can easily grasp the current position of the monitoring terminal and the position of the monitoring point visually.

The specific area monitoring system according to claim 3 of the present invention is the specific area monitoring system according to claim 2,
The monitoring apparatus displays the monitoring point registration position in the route image so that the selection operation can be performed, and receives a movement instruction from a monitor by a selection operation of the monitoring point registration position on the route image.
According to this feature, since the movement instruction is received by selecting and operating the monitoring point registration position on the route image, the monitor can confirm the position of the desired monitoring point on the route image. Since it can be specified, the operability of the movement instruction in the monitoring device can be improved.

The specific area monitoring system according to claim 4 of the present invention is the specific area monitoring system according to claim 2 or 3,
The monitoring device displays the monitoring point registration position in the route image so that the selection operation can be performed, and receives a deletion instruction from the monitor by a selection operation of the monitoring point registration position on the route image and a predetermined deletion operation. , Sending a request to delete the selected monitoring point registration position to the monitoring terminal,
The monitoring terminal is characterized in that the monitoring point information of the selected monitoring point registration position stored in the monitoring point information storage means is deleted based on reception of the deletion request.
According to this feature, the monitor can delete the monitoring point registration position that is no longer necessary while confirming the position of the monitoring point on the route image. Therefore, the monitoring point can be easily changed. be able to.

A monitoring system for a specific area according to claim 5 of the present invention is the monitoring system for a specific area according to any one of claims 1 to 4,
The position specifying means includes a sign detection unit that detects signs provided at predetermined intervals on the movement route, and the sign detection unit counts the number of signs from a reference position on the movement route, thereby moving the movement. It is characterized by specifying the current position on the route.
According to this feature, by setting a predetermined interval according to the required position accuracy, it is possible not only to construct a position specifying means with desired accuracy with a simple configuration, but also to include only signs on these movement paths. Since it is provided, the movement path can be easily reused.

  Examples of the present invention will be described below.

  An embodiment of the present invention will be described with reference to the drawings. First, FIG. 1 is a diagram showing a configuration of a monitoring system for a specific area in the embodiment of the present invention.

  As shown in FIG. 1, the specific area monitoring system of the present embodiment includes a mobile terminal 1 that moves on a moving rail 200 installed on a ceiling or the like of a room to be monitored in the specific area, and the mobile terminal 1. Browsing as a monitoring device having an Internet connection function, which is connected to the monitoring terminal 10 through the router 4 and the Internet network 5 so as to be able to perform data communication. And a personal computer (browsing PC) 6.

  Although this embodiment shows an example in which a personal computer is used as a monitoring device, the present invention is not limited to this, and other than these personal computers, for example, a mobile phone having an Internet connection function is used. Is also possible.

  In the monitoring system of the present embodiment, the control computer (control) in which data such as various settings of the mobile terminal 1, a rail map described later, and a monitoring schedule including the contents of the monitoring operation in automatic monitoring is mounted on the mobile terminal 1. A personal computer for administrator (PC for administrator) 3 for transmission to a PC 100 is connected to the mobile terminal 1 via the router 4 and the wireless LAN transceiver 2 so as to be able to perform data communication with the local area network (LAN). The administrator PC 3 can access the control PC 100 via the LAN, and the administrator PC 3 can perform various initial settings and change settings of the mobile terminal 1.

  First, the mobile terminal 1 used in the present embodiment will be described with reference to FIGS. 1, 2, and 4. The external appearance of the mobile terminal 1 is as shown in FIG. A web having a surveillance camera capable of horizontal rotation (panning) and vertical movement (tilting) on the lower surface of a movable carriage 11 that can move on a moving rail 200 that is I-shaped in cross-section and is installed on a ceiling or the like. The camera 110 is connected so as to be suspended, and the Web camera 110 is housed in a protective glass having a semispherical transparency. That is, the Web camera 110 corresponds to the imaging device of the present invention.

  Further, the outer periphery of the mobile terminal 1 is covered with a protective cover 1 ″ made of steel, and various devices are included in the protective cover 1 ″, while wireless data with the wireless LAN transceiver 2 is included. The wireless LAN transceiver 120 that performs communication is fixed to the mobile carriage 11 so as to be exposed to the outside of the protective cover 1 ″ in order to perform good wireless communication (see FIG. 2).

  As shown in FIG. 2, the Web camera 110 used in this embodiment includes a support arm 112 that is provided on a substantially cylindrical base 110 so as to be rotatable in a horizontal direction, and a shaft that is rotatable on the support arm 112. The camera unit 113 is supported, and by rotating the support arm 112, the orientation of the camera unit 113 can be changed (panned) by 340 degrees, and the camera supported by the support arm 112 is supported. The direction of the camera unit 113 can be changed up and down by moving (tilting) the unit 113 in the vertical direction.

  An imaging camera mounted in the camera unit 113 has an autofocus function and a zoom function (optical or digital), and a zoom command included in an external PTZ (pan / tilt / zoom) setting command. Thus, zoom-in and zoom-down can be remotely operated from the outside, and the horizontal direction of the camera unit 113 is determined by a pan command included in the PTZ setting command, and by a tilt command included in the PTZ setting command. The camera unit 113 can be remotely controlled from the outside in the vertical direction. As the Web camera 110, a commercially available Web camera, specifically, a network camera SNC-RZ30N (manufactured by Sony Corporation) Name) can be preferably used.

  The Web camera 110 used in this embodiment has a Web function inside, and as shown in FIG. 5, an image captured by the imaging camera is controlled via the wireless LAN transceiver 120 and the control PC 100. It can be distributed to the personal computer 3 and the viewing PC 6, and information on the horizontal rotation angle (pan) from the reference angle position at that time, and information on the vertical angle (tilt) at that time (specifically Can be transmitted to an external device such as the control PC 100 or the like, and information such as the zoom level at that time is within a range of +25 degrees in the horizontal upper part to −90 degrees in the vertical direction). The control PC 100, the administrator PC 3, and the browsing PC 6 can receive and display images captured by these imaging cameras. By transmitting status data (described later) including the PTZ information received by the control PC 100 to the browsing PC 6, the viewing PC 6 has a horizontal rotation angle (pan angle) from the reference angle of the Web camera 110 at that time, The tilt angle and zoom level can be grasped.

  In addition, the Web camera 110 used in the present embodiment receives the PTZ setting command including the horizontal rotation instruction, the imaging direction up / down instruction, and the zoom up / zoom down instruction from the control PC 100, thereby receiving the reception. The control PC 100 performs horizontal rotation, up / down of the imaging direction, zoom up / zoom down based on the PTZ setting command, and the control PC 100 displays these PTZ setting commands on the browsing PC 6 to be described later. The Web camera 110 performs the operation of the content operated on the browsing PC 6 by transmitting based on the operation information transmitted from the browsing PC 6 by a predetermined operation on the main page (see FIG. 17). It has become so.

  First, the moving rail 200 used in this embodiment will be described with reference to FIG. 2 and FIG. 3. As shown in FIG. 2, the moving rail 200 used in this embodiment has an I-shaped cross section. Are formed by connecting each unit rail 201 of a predetermined length of 3 m with a connecting plate 202 and a fixing bolt 203. These unit rails 201 are not only linear straight unit rails, There is also a curved unit rail curved at a predetermined angle (see FIG. 20), and by combining these, it is possible to form various endless or endless movement paths. That is, the moving rail 200 corresponds to the moving path of the present invention.

  In addition, a home-side end portion serving as an end portion of the moving rail 200 that is connected to form a moving path having a predetermined shape, and an end portion on the home side are provided on one side surface of the moving rail 200 of the end-side end portion. A home detection piece 204 and an end detection piece 205 having a plate-like portion protruding from the side surface of the moving rail 200 for detecting the end portion on the end side by the control PC 100 mounted on the moving carriage 11 are provided.

  Further, as shown in FIG. 3, the distance from the end on the home side on which the home detection piece 204 is provided on the surface opposite to the side on which the home detection piece 204 or the end detection piece 205 is provided. A count mark 207 is affixed every 250 mm, which is a predetermined interval, and the moving carriage 11 passes between the rails only on one side of each rail at a position below the count mark 207. A preset mark 208 is pasted for detecting this and correcting the movement distance or specifying the movement direction. For this reason, the number of count marks 207 attached to one moving rail 200 is twelve. In this embodiment, the interval between the count marks 207 is 250 mm, but the present invention is not limited to this, and these intervals are the size of the movable carriage 1, the required position accuracy, and the moving speed. For example, it may be 50 mm.

  Further, at a position below the preset mark 208, a triple power supply rail 209 for supplying AC power to the mobile carriage 11 is provided, and the AC power from the power supply rail 209 is converted into DC. It is used as electric power for each device in the mobile carriage 11. Note that reference numeral 206 in FIG. 3 denotes a carriage stop provided at the end of the moving rail 200.

  In the mobile carriage 11 of the mobile terminal 1 of this embodiment, the movement control of the mobile carriage 11 and the Web camera 110 are connected via a hub (HUB) built in the wireless LAN transceiver 120. Operation control, a control PC 100 for transmitting a main page (see FIG. 17) including a monitoring image captured by the Web camera 110 and a simple map image to be described later to the viewing PC 6, and a travel for moving the mobile carriage 11 Motor 140, a motor driver unit 130 that performs operation control of the traveling motor 140 according to an instruction from the control PC 100, and a predetermined DC power source from an AC power source that is supplied from the power supply rail 209 of the moving rail 200 to each device. AC / DC power supply unit 160 (24V), 161 (12V) 162 (3.3V) is provided.

  In addition, as shown in FIG. 1, the control PC 100 has a count sensor 154 (see FIG. 4A) that is a photoelectric sensor that detects the count mark 207 and a preset that is a photoelectric sensor that detects the preset mark 208. A sensor 155 is connected, and detection signals of the count mark 207 and the preset mark 208 by the count sensor 154 and the preset sensor 155 are input to the control PC 100, so that the control PC 100 can detect the position, moving direction, and speed of the movable carriage 11. Etc. can be grasped.

  Further, the control PC 100 is connected with a home detection sensor 152 including a photo sensor for detecting the home detection piece 204 and an end detection sensor 153 including a photo sensor for detecting the end detection piece 205. Based on input of detection signals of the home detection piece 204 and the end detection piece 205 from the detection sensor 152 and the end detection sensor 153, it is possible to grasp that the mobile carriage 11 has reached the end on the home side or the end on the end side. Thus, it is possible to perform predetermined processing according to the grasped situation, for example, processing such as reversing the moving direction of the moving carriage 11 in the motor driver unit 130 based on the detection signal from the end detection sensor 153. It has become.

  The moving carriage 11 is provided with a limit sensor 151 composed of a photosensor at the same height position as the home detection sensor 152 and the end detection sensor 153 at the substantially central position in the moving direction of the moving carriage 11. The detection signal of the home detection piece 204 or the end detection piece 205 by the limit sensor 151 is directly input to the motor driver unit 130 so that the detection signal from the limit sensor 151 is input. The motor driver unit 130 immediately stops the operation of the traveling motor 140, and the home detection piece 204 and the end detection piece 205 are detected by the home detection sensor 152 and the end detection sensor 153 for some reason. Even if the traveling of the moving carriage 11 still does not stop Is adapted to travel of the cart 11 is forcibly stopped by the detection of home detection piece 204 and end detection piece 205 by the limit sensor 151.

  A more detailed configuration of the mobile carriage 11 used in this embodiment is as shown in FIGS. 4A to 4C. The wireless LAN transceiver 120, the traveling motor 140, the control PC 100, and the motor described above are used. The driver unit 130, the AC / DC power supply unit 160 (24V), 161 (12V), 162 (3.3V) are arranged as shown in FIG. A horizontal roller 172 that is provided so as to sandwich the wide portion of the moving rail 200 so as to be movable, and the upper and lower ends of the moving rail 200 that are positioned in a side recess of the moving rail 200. A total of four pivotable ones are provided at both ends in the moving direction of the movable carriage 11 arranged so as to be in contact with the lower surface and the upper surface of the wide portion. The movable carriage 11 is movably fixed to the moving rail 200 by the horizontal roller 172 and the vertical roller 171, and contacts the upper surface of the lower wide portion of the moving rail 200. The drive roller 141 provided in this manner is rotationally driven by the travel motor 140 so that the mobile carriage 11 travels on the travel rail 200. That is, the mobile carriage 11 corresponds to the mobile carriage apparatus of the present invention.

  Note that reference numeral 173 in FIGS. 4A to 4C denotes a trolley for slidingly contacting the power supply rail 209 provided on the moving rail 200 to receive an alternating current.

  Next, the control PC 100 used in the present embodiment will be described. Although the control PC 100 is small in size, it is assumed to have the same functions as those of a normal personal computer. In the data bus 101 for transmitting and receiving data, the position specification processing of the mobile carriage 11 executed by the control PC 100 based on the operating system program and the processing program stored in the storage unit 105 described later, the specified position information and Web CPU 102 for performing various processing such as processing for transmitting status data including PTZ information acquired from camera 110, movement control of mobile carriage 11, operation control processing for Web camera 110, work memory for various processing, and display RAM 103 used as the memory of the And RTC 104 that outputs calendar information, a non-volatile storage unit 105 such as a flash memory card, a display I / F 106 for connecting a display display or the like as necessary, and an input device such as a keyboard or a mouse as necessary. A communication unit 109 for performing data communication with the Web camera 110, the browsing PC 6 and the administrator PC 3 via an input I / F 107 for connection and a hub (HUB) built in the wireless LAN transceiver 120, The motor driver unit 130, the home detection sensor 152, the end detection sensor 153, the count sensor 154, and the preset sensor 155 are connected to input signals from these sensors and For outputting control commands A digital I / O108 is a connected computer. That is, the communication unit 109 corresponds to the communication unit of the present invention, and the control PC 100 corresponds to the control unit of the present invention.

  In the storage unit 105 of the present embodiment, in addition to the operating system program and the processing program as described above, as shown in FIG. 6, rail map data and monitoring schedule data transmitted from the administrator PC 3 are displayed. As will be described in detail later, status data that can specify the current position of the mobile carriage 11, the current PTZ information of the Web camera 110, etc., or a fixed point on the rail map data registered by the registration operation by the supervisor ( Fixed point data indicating a registered position) is stored. A list of data stored in the storage unit 105 is shown in FIG.

  First, the rail map data will be described. As shown in FIG. 8, the rail map data includes a movement path (moving rail 200) formed by connecting the unit rails 201, in other words, an arrangement state of the unit rails 201 (hereinafter referred to as the rails). , Referred to as a rail map), and includes a header and a count mark list.

  The header constituting the rail map data will be described. As shown in FIG. 8A, the name of the rail map indicated by the rail map data and the home detection piece 204 with respect to the count mark 207 in the rail map. Consists of a right end number indicating the serial number assigned to the count mark 207 at the right end and a left end number indicating the serial number assigned to the count mark 207 at the left end when a serial number is assigned from 0 to the starting point Is done.

  Here, the right end number will be described in detail. In the rail map, on the basis of the home detection piece 204, the count mark 207 affixed to the unit rail 201 is incremented clockwise from 0 to 1 at a time. When a serial number is assigned in the above format, the count mark 207 pasted immediately before the first end detection piece 205 provided clockwise (rightward) from the home detection piece 204, that is, the right end This is a serial number assigned to the count mark 207.

  Further, the left end number will be described in detail. In the rail map, the count mark 207 affixed to the unit rail 201 is set -1 to 1 in the counterclockwise direction (left direction) with reference to the home detection piece 204. When a serial number is assigned in the form of subtraction, the count mark 207 pasted immediately before the first end detection piece 205 provided counterclockwise (leftward) of the home detection piece 204, that is, This is a serial number assigned to the leftmost count mark 207.

  It is possible to connect the unit rails 201 to form an endless movement path (closed path). However, even when the closed path is formed, the home detection piece 204 and the end detection piece 205 are included in the closed path. The right end number and the left end number of the header can be set based on the home detection piece 204 and the end detection piece 205.

  The count mark list constituting the rail map data will be described. As shown in FIG. 8B, the count mark list includes various information on the count mark 207 pasted on the rail map indicated by the rail map data. Specifically, in correspondence with the count mark number indicating the serial number of the count mark 207 counted from the home detection piece 204, a serial number is assigned to the preset mark 208 from 0 starting from the home detection piece 204, similarly to the count mark 207. In this case, a preset mark number indicating a serial number assigned to the preset mark 208 pasted on the unit rail 201 on which the count mark 207 is pasted, and a rail map based on the rail map data, As shown in the rail map section of FIG. When displaying as a simple map image, the X coordinate indicating the horizontal position of the count mark 207, the Y coordinate indicating the vertical position of the count mark 207, and the type of the unit rail 201 to which the count mark 207 is attached ( In this embodiment, when the type of the unit rail 201 is a right curve or a left curve), the movable carriage 11 rotates at the count mark 207. And a correction angle indicating an approximate value of the existing angle.

  That is, the count mark 207 attached to the unit rail 201 that forms the moving path (moving rail 200) of the present embodiment is given a count mark number that is a serial number that does not overlap each other. By specifying the count mark number assigned to the count mark 207 in the vicinity of the moving carriage 11, the current position on the moving path can be specified. That is, the count mark number assigned to the count mark 207 in the vicinity of the mobile carriage 11 corresponds to the current position of the present invention.

  Here, the correction angle will be described. When the movable carriage 11 is rotated by about 15 degrees by the curved unit rail 201, the correction angle is 15 degrees on the count mark 207 closest to the movable carriage 11. The other count marks 207 are set to 0 degrees. By using this correction angle, every time the correction angle of the unit rail 201 on the curve reaches the set count mark 207, the correction angle is cumulatively added, so that the unit rail 201 on the curve is accumulated. The traveling direction (angle) of the moving carriage 11 moving on the top can be calculated for each predetermined angle unit. This calculation method is preferable because the correction angle can be easily set as compared with the case where the correction angle is strictly set for each count mark 207.

  For example, as shown in FIG. 20 and as shown in a broken line circle in the rail map portion of FIG. 17, two unit rails 201 on a straight line and one unit rail 201 on a curve are joined together. An example of the count mark list in the rail map is shown in FIG. The unit rail 201 on the straight line, which is the first rail, has 12 count marks 207 assigned -18 to -7 as count mark numbers and one preset mark assigned -1 as a preset mark number. 208 is attached. Further, an end detection piece 205 is provided on the surface opposite to the surface on which the count mark 207 to which −18 is attached is pasted. Further, as shown in the figures, the X coordinate is sequentially changed from 1 to 12, and the Y coordinate is fixed to 1. When displaying as a two-dimensional simple map image, 12 squares (display magnification is 1). In this case, as shown in FIG. 17, when the display magnification is 10 times, it is displayed as a horizontal straight line consisting of about 1 square (1.2 squares).

  In addition, the unit rail 201 on the straight line which is the second rail has 12 count marks 207 to which -6 to 5 are assigned as count mark numbers and one preset mark to which 0 is assigned as a preset mark number. 208 is attached. Furthermore, a home detection piece 204 is provided on the surface opposite to the surface on which the count mark 207 to which 0 is given is pasted. Further, as shown in the figures, the X coordinate is sequentially changed to 13 to 23, the Y coordinate is fixed to 1, and when displayed as a two-dimensional simple map image (see the rail map portion in FIG. 17). Is displayed as a horizontal straight line consisting of 12 squares (when the display magnification is 1, and when the display magnification is 10 times as shown in FIG. 17, it is about 1 square (1.2 squares)). Become.

  The curved unit rail 201, which is the third rail, includes 12 count marks 207 assigned 6 to 17 as count mark numbers and one preset mark 208 assigned 1 as a preset mark number. And are pasted. Further, as shown in the drawings, the X coordinate gradually changes from 24 to 32, and the Y coordinate also gradually changes from 1 to 10, and a two-dimensional simple map image (see the rail map portion in FIG. 17). Is displayed as a circular arc of 90 squares of 12 squares (when the display magnification is 1, when the display magnification is 10 as shown in FIG. (1.2 squares)).

  Next, the status data will be described. As shown in FIG. 7B, the status data indicates the control state of the mobile terminal 1 (in this embodiment, any one of standby, moving, schedule, and system). The state, the position where the mobile terminal 1 is on the rail map, the position indicated by the count mark number and the preset mark number, the target indicating the position and direction of movement of the mobile terminal 1 on the rail map, and the mobile terminal 1, PTZ information (pan, tilt, zoom) indicating the horizontal and vertical rotation angles and zoom degrees of the web camera 110 mounted in 1, and the traveling direction of the movable carriage 11 rotated by the curved unit rail 201 ( Angle).

  In other words, the mobile terminal 1 (control PC 100) automatically starts moving until the home detection piece 204 is detected when the power is turned on, and counts as the home detection piece 204 is detected. The number of the mark 207 or the number of the preset mark 208 is incremented by 1 (if it is moving clockwise, it is decremented by 1 if it is moving counterclockwise) and sent to the viewing PC 6 in advance. In the rail map data (see FIG. 8), the X coordinate and the Y coordinate are stored in association with the count mark number, so that the count mark 207 or preset mark added or subtracted as described above. By transmitting the status data including the number 208 to the viewing PC 6, based on the rail map data and the status data, The horizontal and vertical positions on the simplified map image dimensions (see rail map of FIG. 17), and to be able to identify at all times based on the count mark number.

  Further, the traveling direction (angle) of the moving carriage 11 rotated by the curved unit rail 201 will be described. The correction angle is stored in association with the count mark number by the rail map data (see FIG. 8). Thus, the control PC 100 can specify how many times the traveling direction (angle) of the mobile carriage 11 should be corrected based on the count mark number. Specifically, in this embodiment, when passing through the clockwise curvilinear unit rail 201, a total of 90 degrees is added to the rotation angle by 15 degrees, and the counterclockwise curvilinear unit rail 201 is When passing, a total of 90 degrees is subtracted by 15 degrees from the rotation angle, so that the traveling direction (angle) of the mobile carriage 11 is always specified.

  As described above, by using the status data and the rail map data, the current position and the imaging direction of the mobile terminal 1 at that time are specified in the viewing PC 6 to which these data are transmitted, and the rail map unit of FIG. As shown in FIG. 2, in the two-dimensional simple map image to be described later displayed on the browsing PC 6, the specified current position and imaging direction are displayed so that the supervisor can visually identify with a thick line camera icon. It has come to be.

  In addition, a description will be given of a target indicating the position and moving direction of the mobile terminal 1 on the rail map included in the status data of the present embodiment. The movement direction (in this embodiment, the clockwise direction is the forward direction, the counterclockwise direction is the reverse direction), and the movement that indicates the control content that is executed when moving to the position specified by the count mark number It consists of post-tasks. The post-movement task includes PTZ information (pan, tilt, zoom) indicating control contents with respect to the imaging direction of the Web camera 110, imaging indicating whether a still image is acquired from the Web camera 110, and a count mark. And a rest time indicating a rest time at the position specified by the number. The target only needs to have at least the count mark number or the moving direction set. If only the count mark number is set, the target moves clockwise (to the right) to the position specified by the count mark number. If only the movement direction is set, the movement is continued in the movement direction.

  Next, the PTZ information will be described. As shown in FIG. 7C, the PTZ information is a pan (P. present embodiment) indicating a rotation angle (pan position) in the horizontal direction from the reference angle position of the Web camera 110. Then, the tilt (T. In this embodiment, 0 to 115 degrees) indicating the rotation angle (tilt position) in the vertical direction from the reference angle position of the Web camera 110, and the zoom of the Web camera 110 Zoom (Z. In the present embodiment, 1 to 25 times).

  The PTZ information included in the status data is angle information (pan information) from the reference angle of the camera unit 113 of the Web camera 110, and the direction of the mobile carriage 11 on which the Web camera 110 is mounted also depends on the movement route. Since the actual imaging direction on the two-dimensional simple map image in this embodiment does not match the angle information (pan information) based on the PTZ information, the traveling direction (angle) of the mobile carriage 11 and the Web camera It is necessary to specify the actual imaging direction on the two-dimensional simple map image by adding the rotation angle (pan angle) of the camera unit 113 of 110, but in this embodiment, status data (FIG. b) See), since the traveling direction (angle) of the moving carriage 11 and the PTZ information can always be specified. By adding, so that the actual imaging direction on a two-dimensional simplified map image can be easily calculated.

  Next, fixed point data will be described. As shown in FIG. 7 (d), a fixed point number indicating a numerical value (in this embodiment, a serial number uniquely assigned) that can individually identify the fixed point, and the fixed point is a movement path. A count mark number indicating that it is a specific point (count mark 207) above (see the rail map in FIG. 8), PTZ information (pan, tilt, zoom) indicating the imaging direction of the Web camera 110 at a fixed point, and The traveling direction (angle) of the movable carriage 11 indicates the angle at which the movable carriage 11 rotates from the home detection piece 204 to the count mark 207 of the count mark number. That is, the fixed point data corresponds to the monitoring point information of the present invention.

  As described above, since the count mark number is stored for each fixed point in the fixed point data, the X coordinate and the Y coordinate are stored in association with the count mark number by the rail map data (see FIG. 8). Thus, the horizontal position and the vertical position on the two-dimensional simple map image (see the rail map portion in FIG. 17) can be specified based on the count mark number. Further, since the PTZ information and the traveling direction (angle) of the moving carriage 11 are stored for each fixed point, the imaging direction (only in the horizontal direction) of the Web camera 110 when the moving carriage 11 moves to the fixed point is specified. It can be done.

  As described above, when the fixed point data and the rail map data are used, as shown in the rail map portion of FIG. 17, in the two-dimensional simple map image displayed on the viewing PC 6, for example, the fixed point data is displayed by a thin line camera icon. The position of the fixed point registered as and the imaging direction can be displayed in an identifiable manner.

  Next, the monitoring schedule data will be described. As shown in FIG. 18, a schedule list covering the monitoring schedule stored in the storage unit 105 of the control PC 100, and a header and a fixed point list indicating each monitoring schedule are included. Composed.

  First, a schedule list covering the monitoring schedule will be described. As shown in FIG. 18A, a schedule list number indicating a serial number (identification number) of the monitoring schedule in the schedule list and a monitoring schedule defined in a header described later. Is composed of a schedule number that can be individually identified, and a start date and time that indicates the date and time when the execution of the monitoring schedule starts. For example, the start date and time is expressed as 9:23 on October 13, 2004.

  Next, the header constituting each monitoring schedule will be described. As shown in FIG. 18 (b), the header is composed of a name of the monitoring schedule and a schedule number capable of individually identifying the monitoring schedule.

  Next, the fixed point list constituting each monitoring schedule will be described. As shown in FIG. 18C, the fixed point list number indicating the serial number (identification number) of the fixed point in the fixed point list and the fixed point data (see FIG. 7 (d)) as a flag indicating the fixed point number that can individually identify the fixed point, the movement start time to the fixed point, and whether to acquire a still image from the Web camera 110 after moving to the fixed point Imaging after movement, and a stationary time after movement indicating a period of time after moving to the fixed point. Thus, the fixed point list defines a monitoring schedule in which the fixed points determined by the fixed point list numbers are sequentially moved in the order of the serial numbers determined by the fixed point list numbers. Therefore, the movement start time indicates how many minutes and seconds after which the movement to each fixed point starts, starting from the execution start date and time of the monitoring schedule. For example, the movement start time is expressed as 02 minutes 10 seconds.

  Each monitoring schedule will be specifically described. FIG. 18D shows a monitoring schedule whose name is monitoring course 1 and whose schedule number is 1. The monitoring schedule defined by this fixed point list starts with the movement to the fixed point whose fixed point number is 1 in the fixed point data (see FIG. 7 (d)) with the start of the monitoring schedule, and for 5 seconds after the movement. Quiesce. Then, when 1 minute elapses after the start of the monitoring schedule, the movement to the fixed point whose fixed point number is 5 in the fixed point data is started, and is stationary for 20 seconds after the movement. Furthermore, when 2 minutes and 30 seconds have elapsed after the start of the monitoring schedule, the movement to the fixed point whose fixed point number is 7 in the fixed point data is started, and after the movement, the still image is acquired from the Web camera 110. It has become.

  In the present embodiment, the control PC 100 of the mobile terminal 1 causes the home provided on the unit rail 201 by the home detection sensor 152, the end detection sensor 153, the count sensor 154, and the preset sensor 155 as it moves on the rail map. A mechanism (function) for detecting the detection piece 204, the end detection piece 205, the count mark 207, and the preset mark 208 and specifying the current position of the mobile carriage 11 based on these detections is provided. Hereinafter, a mechanism for identifying the current position of the mobile carriage 11 will be described.

  First, the processing when the home detection piece 204 is detected by the home detection sensor 152 will be described. As shown in FIG. 9, when the control PC 100 receives the detection signal from the home detection sensor 152, the status data (FIG. 7 ( b)) is initialized. Specifically, the count mark number and preset mark number are cleared to zero. In this way, the position where the home detection piece 204 is provided is used as a reference position when counting the count mark number as it moves.

  In this embodiment, when the power is turned on, the control PC 100 sets the status data state to a system mode that does not accept an operation from the browsing PC 6 and moves to the motor driver unit 130, for example, clockwise. Send a command to that effect and start moving. Then, the control PC 100 performs processing when the home detection piece 204 is detected by the home detection sensor 152, sets the status data state to standby, and shifts to a state in which an operation from the viewing PC 6 can be accepted. . In this way, before actually monitoring, the control PC 100 moves the mobile terminal 1 to the home and initializes the status data, so that the serial number of the count mark 204 can be calculated with the subsequent movement. Has been.

  Next, a process when the end detection piece 205 is detected by the end detection sensor 153 will be described. As shown in FIG. 10, when the control PC 100 receives a detection signal from the end detection sensor 153, the movement direction is reversed. A moving direction reversal command indicating this is transmitted to the motor driver unit 130. In this way, when the position where the end detection piece 205 is provided, that is, the right end or the left end of the rail map is reached, control is performed so as not to proceed further. Note that the command indicating that the moving direction is reversed is a command indicating that the movement proceeds counterclockwise when traveling in the clockwise direction, and that the movement proceeds clockwise when traveling in the counterclockwise direction. Further, after changing the movement direction, the control PC 100 sets the movement direction included in the target of the status data (see FIG. 7B) as the changed movement direction.

  Next, the processing when the count mark 207 is detected by the count sensor 154 will be described. As shown in FIG. 11, when the control PC 100 receives the detection signal from the count sensor 154, the status data (FIG. 7B). A count mark number update process is performed in which the count mark number included in the position (see) is updated by 1 (when the moving direction is clockwise, or when the counterclockwise direction is rotated, 1 is subtracted). That is, every time the count mark 207 is passed, the count mark number assigned to the passed count mark 207 is updated to identify the count mark number assigned to the count mark 207 in the vicinity of the mobile carriage 11. The count mark update process to be performed corresponds to the current position specifying means of the present invention.

  In addition, the count mark update process, which is the position specifying means of the present invention, uses a marker (count sensor 207) provided at a predetermined interval (250 mm) on the moving path (the moving rail 200 formed by connecting the unit rails 201). It has a sign detection unit (count sensor 154) to detect, and by counting the number of signs (count mark number) from a reference position (home detection piece 204) on the movement path by the sign detection unit, The current position is specified.

  Then, the correction angle stored in the rail map data (see FIG. 8) is extracted in association with the updated count mark number. If the correction angle is not 0, the travel direction (angle) of the moving carriage 11 in the status data is extracted. Add and update the correction angle.

  Furthermore, the control PC 100 determines whether or not the updated count mark number matches the count mark number included in the target of the status data. Send a stop command to stop the movement of

  Then, if the PTZ information included in the target of the status data is set, the control PC 100 performs a PTZ setting command transmission process for transmitting to the Web camera 110 a PTZ setting command indicating that the PTZ information is set. If imaging included in the target of the status data is set, a still image acquisition command indicating that a current still image is acquired is transmitted to the Web camera 110 and a still image is received from the Web camera 110. If the stationary time included in the status data target is set, the system waits until the stationary time elapses.

  As described above, the control PC 100 updates the count mark number based on the detection of the count mark 207 by the count sensor 154 accompanying the movement, so that the two-dimensional simplified map image on the moving route of the moving carriage 11 ( The current position on the rail map) can be specified, and when the specified current position matches the target position, that is, when the target position is reached, the movement of the movable carriage 11 is stopped, Perform a predetermined post-movement task.

  Next, the processing when the preset mark 208 is detected by the preset sensor 155 will be described. This preset mark 208 is for correcting the count mark number. As shown in FIG. The expected number of the count mark number is calculated based on the preset mark number.

  Here, the predicted number of the count mark number will be described. The predicted number indicates the predicted value of the count mark number assigned to the count mark 207 at the left end of each unit rail 201. Specifically, the expected number is calculated as (preset mark number) × (number of count marks 207 attached to one unit rail 201) + (initial addition value). The initial addition value is the count mark number assigned to the count mark 207 pasted on the left end of the unit rail 201 in the unit rail 201 connected to the right side of the unit rail 201 provided with the home detection piece 204. Has been.

  For example, the number of count marks 207 attached to one unit rail 201 is 12, the initial addition value is 6, the count mark number is 41 (correctly 42), and the preset mark number is 2 (correctly 3). ), The case where the detection signal is received from the preset sensor 155 will be described. The expected number is (2) × (12) + (6) = (30).

  Then, the control PC 100 calculates a difference (absolute value) between the calculated expected number and the count mark number of the status data (see FIG. 7B), and pastes it on (one difference) / (one unit rail 201). It is determined whether or not the number of count marks 207 being within a predetermined range, in this embodiment, between 90% and 110%. This is because the expected number of the number of count marks 207 pasted on one unit rail 201, that is, the expected number of one rail is shifted, in other words, the preset mark number is at least 1. This means that there is a gap.

  For example, the number of count marks 207 attached to one unit rail 201 is 12, the initial addition value is 6, the count mark number is 41 (correctly 42), and the preset mark number is 2 (correctly 3). ), When the detection signal is received from the preset sensor 155, the expected number is (2) × (12) + (6) = (30), and the difference is (41) − ( 30) = (11), and the ratio is (11) / (12) = about 91.6%.

  The control PC 100, which has confirmed that the preset mark number is almost deviated, corrects the preset mark number based on the expected number, and records the correction in a correction history (not shown) stored in the storage unit 105. . Further, the predicted number is recalculated based on the corrected preset mark number, and the difference between the count mark number and the predicted number is also recalculated.

  Thereafter, the control PC determines whether (difference) / (expected number) is within a predetermined range based on the calculated expected number and the difference, in this embodiment, whether it is between 0% and 10%. Determine. This means that the count mark number of the status data (see FIG. 7B) is shifted by at least 1 or more.

  For example, the number of count marks 207 affixed to one unit rail 201 is 12, the initial addition value is 6, the count mark number is 41 (correctly 42), and the preset mark number is 3 (correctly 3 ), The case where the detection signal is received from the preset sensor 155 will be described. The expected number is (3) × (12) + (6) = (42), and the difference is (41) − ( 42) = (1) (absolute value), and the ratio is (1) / (42) = about 2%.

  The control PC 100 that has confirmed that the count mark number has shifted by at least one or more corrects the count mark number based on the expected number. Specifically, the control PC 100 changes the count mark number to match the expected number, and corrects the fact. Is recorded in a correction history (not shown) stored in the storage unit 105. Further, the difference between the count mark number and the expected number is recalculated based on the corrected count mark number. Note that the difference calculated after correction is always zero.

  Thereafter, the control PC 100 determines whether or not the recalculated difference is 0 based on the preset mark number and the count mark number corrected as necessary. If the difference is not 0, that is, the correction is performed. If not, or if the correction fails, an emergency correction process such as sending an e-mail to explain the situation to the administrator PC 3 is performed.

  When the difference is 0, when the control PC 100 receives the detection signal from the preset sensor 155, the control PC 100 updates the preset mark number included in the position of the status data (see FIG. 7B) by one (the movement direction is changed). In the case of clockwise rotation, in the case of counterclockwise rotation, 1 subtraction is updated), and the processing based on the detection of the preset sensor 155 is completed.

  As described above, the control PC 100 detects that the preset mark 208 has become an incorrect numerical value due to erroneous detection of the preset mark 208 or the count mark 207 that has occurred so far, based on the detection of the preset mark 208 by the preset sensor 155 accompanying the movement. The number and the count mark number can be corrected when the error range is a predetermined range.

  In this embodiment, as shown in FIG. 13, the control PC 100 of the mobile terminal 1 performs a timer interrupt process every second based on the reception of the timer interrupt signal from the RTC 104. First, when receiving an interrupt signal from the RTC 104, the control PC transmits a PTZ acquisition command indicating that the PTZ information that can specify the current imaging direction is requested to the Web camera 110, and receives the PTZ information from the Web camera 110. Receive. The control PC that has received the PTZ information rewrites and updates the PTZ information in the status data (see FIG. 7B) with the received PTZ information, and ends the timer interrupt process.

  As described above, the status data (see FIG. 7B) is updated by the control PC 100 based on the detection signals from the various sensors, the count mark number, the preset mark number, the moving direction, and the like. In the interrupt process, the PTZ information is updated every second. For this reason, the current position of the mobile carriage 11 of the mobile terminal 1 and the current imaging direction of the Web camera 110 can always be specified based on the status data.

  In the present embodiment, the control PC 100 of the mobile terminal 1 can distribute a main page for operating the mobile terminal 1 to the browsing PC 6 and perform processing according to the operation received via the main page. ing. Hereinafter, a mechanism for performing processing according to an operation received from the browsing PC 6 will be described with reference to FIGS. 14 and 15.

  First, as shown in FIG. 14, the monitor transmits an authentication page request for requesting an authentication page from the browser software of the browsing PC 6 to the control PC 100, and the control PC 100 authenticates as shown in FIG. Deliver the page. In the authentication page, when the monitor inputs a predetermined user ID and password and operates the OK button, the browser software of the browsing PC 6 issues an authentication request including the user ID and password for requesting authentication. It transmits to control PC100.

  The control PC 100 that has received the authentication request determines whether or not the received user ID and password are registered in a user database (not shown) of the storage unit 105. To deliver.

  As shown in FIG. 17, the main page of the present embodiment includes a rail map section having a display area for displaying a two-dimensional simple map image based on rail map data (see FIG. 7B), and a control. An operation unit for inputting operation details on the PC 100 and a video unit including a display area for displaying an image captured by the Web camera 110 are configured.

  In this embodiment, the rail map unit, the operation unit, and the video unit are formed by programs that can be operated by the browser software of the viewing PC 6, and each program transmits necessary data to the control PC 100 and the Web camera. 110 is provided with a function for appropriately updating the display contents in the display area, but the present invention is not limited to this, and the browser of the PC 6 for viewing the rail map unit, the operation unit, and the video unit is not limited thereto. It may be configured as Web content that can be displayed by software. In this case, the control PC 100 acquires necessary data, generates Web content based on the data, and distributes the page generation function and page distribution function. Just prepare.

  When the program of the rail map unit is executed by the browser software of the viewing PC 6, a rail map data request for requesting rail map data (see FIG. 8) is transmitted to the control PC 100. The control PC that has received the rail map data request performs rail map data transmission processing for transmitting rail map data to the program of the rail map unit.

  The rail map unit program that has received the rail map data has a grid-like 2 in accordance with a series of X and Y coordinates associated with a series of count mark numbers in the count mark list included in the rail map data. In order to display a three-dimensional simple map image (rail map) and to identify a movement path in a two-dimensional simple map image with respect to a series of X coordinates and Y coordinates included in the rail map data, For example, as shown in FIG.

  That is, the two-dimensional simple map image (rail map) in which the movement route is displayed so as to be visible with a thick line enclosed corresponds to the route image of the present invention. Rail map data (see FIG. 8) used for generating a two-dimensional simple map image (rail map) corresponds to the route information of the present invention. Moreover, the memory | storage part 105 (refer FIG. 1) of the monitoring terminal 10 (control PC100) which memorize | stores this rail map data corresponds to the route information memory | storage part of this invention. The rail map data transmission process in which the monitoring terminal 10 (control PC 100) transmits rail map data to the monitoring device (the program of the rail map unit operating on the viewing PC 6) is performed by the route information transmission means of the present invention. Applicable.

  Further, the program of the rail map unit transmits a status data request for requesting status data (see FIG. 7B) to the control PC 100. The control PC that has received the status data request performs status data transmission processing for transmitting the status data to the program of the rail map unit.

  The program of the rail map unit that has received the status data specifies a two-dimensional simple map image (rail) by specifying the X coordinate and the Y coordinate associated with the count mark number of the received status data in the rail map data. The current position of the mobile terminal 1 on the map) is specified, and the current position of the mobile terminal 1 is visually checked by displaying a thick line camera icon as shown in FIG. 17 for the specified X coordinate and Y coordinate. Display as possible.

  That is, the count mark number included in the status data corresponds to the current position information of the present invention. Further, the status data transmission process in which the monitoring terminal 10 (control PC 100) transmits status data to the monitoring device (the program of the rail map unit operating on the viewing PC 6) corresponds to the current position information transmitting means of the present invention. To do.

  When displaying the thick line camera icon, the rail map section program displays a Web camera in a two-dimensional simple map image in the X and Y coordinates associated with the count mark number of the status data in the rail map data. 110, for example, by adding a thick line camera icon as shown in FIG. 17 and adding the PTZ information of the status data and the traveling direction (angle) of the mobile carriage 11 as described above. By tilting and displaying the calculated angle, the imaging direction at that time is displayed so as to be visible. The status data request and display is performed every 2 seconds.

  Further, the program of the rail map section transmits a fixed point data request for requesting fixed point data (see FIG. 7D) to the control PC 100. The control PC that has received the fixed point data request performs fixed point data transmission processing for transmitting the fixed point data to the program of the rail map unit.

  That is, the fixed point data transmission process in which the monitoring terminal 10 (control PC 100) transmits fixed point data to the monitoring device (the program of the rail map unit operating on the browsing PC 6) corresponds to the monitoring point information transmission means of the present invention. To do.

  The program of the rail map unit that has received the fixed point data specifies a fixed point on the rail map by specifying the X coordinate and the Y coordinate associated with the count mark number of each fixed point included in the fixed point data in the rail map data. (Registered position) is specified, and a thin line camera icon is displayed with respect to the specified X coordinate and Y coordinate as shown in FIG. 17, so that a fixed point on a two-dimensional simple map image (rail map) ( The registered position) is displayed so as to be visible and selectable.

  In other words, the viewing PC 6 as the monitoring device of the present invention counts current position information (status data count) on a route image (two-dimensional simple map image (rail map)) generated from route information (rail map data). An area (X coordinate, Y coordinate) corresponding to the current position specified from the mark number) is specified, and the specified area can be identified as the current position of the monitoring terminal (thick line camera icon) and monitoring point information A region (X coordinate, Y coordinate) corresponding to a position (fixed point data count mark number) included in (fixed point data) can be identified, and the identified region can be identified as a monitoring point registration position (thin line camera icon) A route image is generated, and the generated route image is displayed as a main page as shown in FIG. 17 together with an image (video data) of a specific area. It is.

  When displaying the thin line camera icon, the program of the rail map unit uses a two-dimensional simplified map in the X and Y coordinates associated with the count mark numbers of the fixed points included in the fixed point data in the rail map data. In order to specify the imaging direction of the Web camera 110 when moving to the fixed point on the map image (rail map), for example, a thin line camera icon as shown in FIG. 17 is included in the fixed point data as described above. The imaging direction at each fixed point (registered position) is displayed so as to be visible by tilting to the angle calculated by adding the PTZ information of each fixed point and the traveling direction (angle) of the moving carriage 11. The fixed point data request and display are repeatedly executed at predetermined intervals.

  In the present embodiment, a two-dimensional simple map image (rail map), a thin line camera icon, etc. as a fixed point (registered position) displayed on the two-dimensional simple map image (rail map) can be selected. Thus, not only the operation unit program described later but also the rail map unit program can accept operations from the supervisor.

  First, the program of the rail map unit allows the observer to double-click a fixed point displayed in the two-dimensional simple map image (rail map), for example, a thin line camera icon as shown in FIG. Thus, the supervisor receives a movement instruction indicating that the mobile terminal 1 is to be moved to the fixed point double-clicked.

  That is, the viewing PC 6 (rail map section program) as the monitoring device of the present invention can select and operate the monitoring point registration position (thin line camera icon) in the route image (two-dimensional simple map image (rail map)). (Double-clickable) is displayed, and a movement instruction from the supervisor is accepted by a selection operation (double-click) of the monitoring point registration position on the route image.

  The program of the rail map unit that accepts that the fixed point is designated transmits a monitoring point movement request including fixed point data (fixed point number, count mark number, PTZ information) associated with the fixed point to the control PC 100 (FIG. (See 17 Fixed point selection acceptance).

  Upon receiving the monitoring point movement request including fixed point data, the control PC 100 counts the count mark number included in the position of the status data (see FIG. 7B) stored in the storage unit 105 and the received fixed point data. The movement direction is determined by comparing with the mark number, and the count mark number of the received fixed point data, the PTZ information, and the determined movement direction are set as targets of the status data (see FIG. 7B). The count mark number, the movement direction, and the PTZ information of the post-movement task are set, and a movement command indicating that the movement is performed in the determined movement direction is transmitted to the motor driver unit 130.

  Note that, based on the processing when the count mark 207 is detected by the count sensor 154 (see FIG. 11), the control PC 100 places the mobile carriage 11 at a position specified by the count mark number included in the status data target. After the movement, the moving carriage 11 is stopped, and the Web camera 110 is set in the imaging direction specified by the PTZ information included in the status data target.

  That is, the control PC 100 as the control means of the present invention transmits from the monitoring device based on a predetermined operation (double click on the thin line camera icon) of the monitoring person in the monitoring device (viewing PC 6 (rail map section program)). The position (count mark number) included in the monitoring point information (fixed point data) is specified based on the received monitoring point movement request (fixed point data associated with the thin line camera icon), and the specified position is reached. Control for moving the moving carriage device (moving carriage 11) is performed (a count mark number and a moving direction are set as status data targets, and a moving command is transmitted to the motor driver unit 130).

  Next, the program of the rail map unit displays an arbitrary position (mass) of the moving route displayed in the two-dimensional simple map image (rail map), for example, surrounded by a thick line as shown in FIG. When the supervisor double-clicks with a mouse at any position in the existing section, the supervisor accepts a movement instruction indicating that the mobile terminal 1 is to be moved to the double-clicked position.

  The program of the rail map unit that accepts that the position is designated transmits a movement request including the count mark number associated with the designated position to the control PC 100.

  The control PC 100 that has received (accepted) the movement request including the count mark number includes the count mark number included in the position of the status data (see FIG. 7B) stored in the storage unit 105, and the received count mark. The movement direction is determined by comparing with the number, and the received count mark number and the determined movement direction are respectively compared with the count mark number included in the target of the status data (see FIG. 7B) and the movement. The movement command indicating that the movement is performed in the determined movement direction is transmitted to the motor driver unit 130.

  Note that, based on the processing when the count mark 207 is detected by the count sensor 154 (see FIG. 11), the control PC 100 places the mobile carriage 11 at a position specified by the count mark number included in the status data target. After the movement, the movable carriage 11 is stopped.

  That is, the control PC 100 as the control means of the present invention controls the movement by the moving carriage device (moving carriage 11) based on the movement information (movement request) transmitted from the monitoring device (browsing PC 6). Based on this, the count mark number and the moving direction are set as the target of the status data, and the moving command is transmitted to the motor driver unit 130).

  Next, the rail map unit program can accept the operation of the display magnification of the rail map from the observer. Specifically, as shown in FIG. Are provided with four buttons for setting the display magnification to 1/1, 1/10, 1/100, and 1/1000 times.

  The program of the rail map unit that accepts that any of these buttons has been operated is configured to display the rail map at the display magnification associated with the button.

  For example, in the example shown in FIG. 17, one rail is displayed on the two-dimensional simple map image as about 1 square (1.2 squares). For example, 12 count marks 207 are pasted on one rail. If this is the case, ten count marks 207 are collected into one square, which corresponds to a display magnification of 10 times.

  Next, when the program of the video section is executed by the browser software of the browsing PC 6, a video data request for requesting video data is transmitted to the Web camera 110. Receiving the video data request, the Web camera 110 transmits the video data to the program of the video unit with the set image size and the number of frames.

  The program of the video unit that has received the video data transmitted from the Web camera 110 displays the received video data in the display area.

  Note that the video data is constantly updated since it is so-called streaming playback that is continuously received from the Web camera 110 and played back.

  Next, when the program of the operation unit is executed by the browser software of the browsing PC 6, various operation buttons as shown in the operation unit of FIG. 17 are displayed, and the operation content can be received from the monitor.

  Here, various operation buttons displayed by the program of the operation unit will be described. The operation buttons are arranged in a 3 × 3 grid for receiving a horizontal rotation operation (pan) and a vertical rotation operation (tilt) on the Web camera 110. An arranged pan / tilt button, a slide bar for accepting a zoom operation on the Web camera 110, a frame number selection box for accepting an operation for setting the number of frames of a delivery video for the Web camera 110, and an image of the delivery video for the Web camera 110 An image size selection box for accepting a size setting operation, a motor control button arranged in a straight line for accepting a movement speed designation operation and a movement direction designation operation of the mobile carriage 11, and the current of the mobile carriage 11 of the mobile terminal 1 Position and PTZ information of Web camera 110 as new fixed points A fixed point registration button that accepts operations for additional registration to point data, and a thin line camera icon as a fixed point (registration position) that can be selected on the two-dimensional simple map image (rail map) as described above After selecting with the mouse, the fixed point deletion button for receiving an operation for deleting the selected fixed point from the fixed point data and the mobile terminal 1 from the manual operation state to the automatic operation state, or from the automatic operation state to the manual operation state. And a mode button for accepting an operation for changing.

  As illustrated in FIG. 15, the program of the operation unit that has received an operation via various operation buttons transmits an operation request including the operation content corresponding to the operation button to the control PC 100.

  First, the control PC 100 that has received a registration request as an operation request indicating that the fixed point registration button has been operated is associated with a new fixed point number for the fixed point data, and the status data (see FIG. 7B). The count mark number included in the position, the PTZ information, and the traveling direction (angle) of the moving carriage 11, the count mark number of the fixed point data (see FIG. 7 (d)), the PTZ information, and the traveling direction of the moving carriage 11, respectively. Register a fixed point (angle) additionally. In this way, the current position of the mobile carriage 11 of the mobile terminal 1 and the PTZ information of the Web camera 110 can be additionally registered in the fixed point data as new fixed points.

  That is, the fixed point data as the monitoring point information of the present invention is stored in response to the reception of the registration request transmitted based on the registration operation of the monitor by the viewing PC 6 (program of the operation unit) as the monitoring device of the present invention. The storage unit 105 that corresponds to the monitoring point information storage unit of the present invention.

  Next, when a deletion instruction indicating that the fixed point deletion button has been operated is received, the program of the operation unit is fixed point data associated with the thin line camera icon as the fixed point selected in the program of the rail map unit A request for a selected fixed point number is transmitted to request a fixed point number. If the fixed point number cannot be received from the program in the rail map unit, the program in the operation unit ends the process. If the fixed point number is received from the rail map portion program, the operation unit program sends a deletion request to the control PC 100 as an operation request indicating that the fixed point deletion button including the received fixed point number has been operated. Send.

  That is, the viewing PC 6 (program of the operation unit) as the monitoring device of the present invention has a monitoring point registration position (X coordinate, Y coordinate of the thin line camera icon) in the route image (two-dimensional simple map image (rail map)). ) Is displayed as selectable (clickable), and a monitoring point registration position selection operation (click) on the route image and a predetermined deletion operation (fixed point deletion button operation) receive a deletion instruction from the supervisor Thus, a request to delete the selected monitoring point registration position is transmitted to the monitoring terminal 10 (control PC 100).

  Then, the control PC 100 that has received the deletion request specifies a fixed point (registered position) to be deleted from the received fixed point number, and fixed point data (information such as a count mark number of the specified fixed point (registered position)) ( (See FIG. 7D). In this way, the fixed point data of the fixed point selected by the monitor is deleted from the storage unit 105 of the control PC 100.

  That is, the monitoring terminal 10 (control PC 100) as the monitoring terminal of the present invention selects the selected (clicked) monitoring point registration position stored in the monitoring point information storage unit (storage unit 105) based on the reception of the deletion request. The monitoring point information (fixed point data) of (the X-coordinate and Y-coordinate of the thin line camera icon) is deleted.

  In addition, the control PC 100 that has received an operation request indicating that the Web camera 110 has been operated, specifically, an operation request indicating that any of the pan / tilt buttons, slide bar, frame number selection box, and image size selection box has been operated. Performs a camera operation command in response to the operation request, specifically, a PTZ setting command transmission process for transmitting a PTZ setting command, a video parameter setting command to the Web camera 110, and the like.

  The video parameter setting command is a command for causing the Web camera 110 to set the number of frames and the image size. The Web camera 110 performs video distribution based on this command and the parameters set by the PTZ setting command. To do. Therefore, processing these operation requests to the Web camera 110 is equivalent to setting the video data received by the video unit.

  Further, the control PC 100 that has received the operation request indicating that the movable carriage 11 has been operated, specifically, the operation request indicating that the motor control button has been operated, receives the cart operation command corresponding to the operation request, specifically, Transmits a movement command for setting a movement direction and a movement speed to the motor driver unit 130.

  FIG. 15 shows a program of the operation unit that receives the operation of the mode button that receives the operation for changing the mobile terminal 1 from the manual operation state to the automatic operation state or from the automatic operation state to the manual operation state. As shown, mode information is transmitted to the control PC 100 as an operation request including the operation content indicating that the mode button has been operated.

  The control PC 100 that has received the mode information performs a schedule process for performing automatic monitoring based on the monitoring schedule data (see FIG. 18) set in advance from the administrator PC 3. This schedule processing will be described below based on FIG.

  When shifting to the schedule processing, the control PC 100 first determines whether the status data (see FIG. 7B) is in a standby state or a schedule state. Change state.

  Note that when the status data status is “moving” or “system”, the processing is terminated without changing the status or performing anything.

  Next, it is determined whether or not the status data status is a schedule. If the status data is not a schedule, that is, if an operation for switching the mode is accepted from the schedule, a stop command for stopping the movement is issued. It transmits to the driver unit 130, and a process is complete | finished. As described above, when the operation of the mode button is accepted during the automatic monitoring, the control PC 100 stops the automatic monitoring and switches to the manual monitoring (status data is in standby).

  When the status data is a schedule, automatic monitoring is performed based on the monitoring schedule data (see FIG. 18) set in advance from the administrator PC 3.

  In automatic monitoring, first, the control PC 100 determines whether or not monitoring schedule data is set, specifically, whether or not a schedule list (FIG. 18A) is set. When the schedule list is not set, the process proceeds to the first process (A), the state of the schedule data is changed from the schedule to the standby state, and the process ends.

  In addition, when the schedule list is set, the control PC 100 sets the schedule number in which the start date and time closest to the current date and time are set after the current date and time among the monitoring schedules included in the schedule list. Extracted as a monitoring schedule for automatic monitoring, and waits until the current date and time reaches the start date and time.

  When the current date / time reaches the start date / time, the control PC 100 reads the monitoring schedule associated with the extracted schedule number, specifically, the fixed point list (see FIG. 18C).

  Then, the control PC 100 performs a fixed point list rearrangement lottery for determining whether or not to change the order of fixed point numbers included in the read fixed point list. If the fixed point list rearrangement lottery is not won, automatic monitoring based on the read fixed point list is started.

  When the fixed point list rearrangement lottery is won, the read fixed point list, that is, the normal fixed point list preset from the administrator PC 3 is stored in the storage unit 105, and the fixed point numbers included in the fixed point list are stored. The fixed point list is reordered to change the order at random. By this fixed point list rearrangement update, automatic monitoring based on a fixed point list indicating that fixed points set in advance from the administrator PC 3 are monitored in an order different from the order set in advance from the administrator PC 3 is started. It will be.

  In this embodiment, only the fixed point numbers included in the fixed point list (see FIG. 18C) are rearranged. However, the movement start time, the shooting after movement, the stationary time after movement, etc. are rearranged or changed. You may do it.

  Then, the control PC 100 starts automatic monitoring based on the fixed point list. In the automatic monitoring, first, the control PC 100 determines whether all fixed point numbers in the fixed point list have been extracted, in other words, whether all fixed points included in the monitoring schedule have been monitored.

  If it is determined that all the fixed point numbers in the fixed point list have been extracted, the control PC 100 ends the monitoring schedule, and whether or not the normal fixed point list is stored in the storage unit 105, that is, is executed. It is determined whether the monitoring schedule is a different monitoring schedule from the monitoring schedule based on the fixed point list rearranged by the fixed point list rearrangement update. When a normal fixed point list is saved, the fixed point list rearranged by the fixed point list rearrangement update is replaced with the saved normal fixed point list, so that the monitoring schedule based on this fixed point list is executed next time. In this case, the monitoring schedule is set in advance from the administrator PC 3. And it returns to the process which determines the state of status data again, and continues automatic monitoring. If the normal fixed point list is not stored, the process immediately returns to the process of determining the status data status, and the automatic monitoring is continued.

  If it is determined that all the fixed point numbers in the fixed point list have not been extracted, the control PC 100 extracts one fixed point number from the fixed point list and sets the fixed point number in the fixed point list (see FIG. 18C). Wait until the associated movement start time has elapsed. The fixed point numbers are extracted from the fixed point list in the order of the fixed point list numbers, that is, in the order of the serial numbers given to the fixed points included in the fixed point list.

  When the movement start time has elapsed, the control PC 100 reads out the fixed point data (see FIG. 7D) based on the extracted fixed point number, and specifies the count mark number and the PTZ information.

  The control PC 100 that has specified the count mark number and the PTZ information includes the count mark number included in the position of the status data (see FIG. 7B) stored in the storage unit 105, and the specified count mark number. Are compared with each other, and the further specified count mark number, the PTZ information, and the determined movement direction are respectively compared with the count mark number included in the target of the status data (see FIG. 7B). The movement direction and the PTZ information of the post-movement task are set.

  Furthermore, in the fixed point list (see FIG. 18C), the post-movement imaging registered in association with the extracted fixed point number and the post-movement stationary time are respectively stored in the status data (see FIG. 7B). Set the task imaging after moving and the rest time.

  As described above, after setting the target of the status data based on the fixed point list and the fixed point data, a movement command indicating movement in the movement direction included in the target is transmitted to the motor driver unit 130.

  Note that, based on the processing when the count mark 207 is detected by the count sensor 154 (see FIG. 11), the control PC 100 places the mobile carriage 11 at a position specified by the count mark number included in the status data target. After the movement, the moving carriage 11 is stopped, the Web camera 110 is set in the imaging direction specified by the PTZ information included in the target of the status data, and further, the imaging or the stand-by time until the stationary time elapses. It comes to perform control.

  As described above, according to the embodiment of the present invention, the monitor moves the monitoring terminal to the fixed point (registered position) that is the monitoring point where the operation of the fixed point registration button that is the registration operation is performed on the browsing PC 6 that is the monitoring device. Is stored in the storage unit 105 of the control PC serving as the monitoring point information storage means by simply double-clicking a thin line camera icon indicating the fixed point (registered position) on the rail map. The position of the selected monitoring point is specified based on the fixed point data serving as the monitoring point information, and the mobile terminal 1 that forms the monitoring terminal automatically moves to the specified position. Since it is controlled by the control PC 100, it is possible to easily monitor the mobile terminal 1 as the monitoring terminal by accurately moving it to a desired monitoring point. That.

  Further, according to the embodiment of the present invention, the current position of the mobile terminal 1 is specified in the control PC 100 of the mobile terminal 1 constituting the monitoring terminal, and the current position and registration operation of the specified mobile terminal 1 are performed. A rail map image that is a route image including a thin line camera icon that can specify the position of a fixed point that is a monitoring point is generated by the viewing PC 6, and the generated rail map image (route image) is displayed in a specific region. Since it is displayed on the main page on the viewing PC 6 together with the image, the supervisor can easily grasp the current position of the mobile terminal 1 and the position of the monitoring point visually.

  Further, according to the embodiment of the present invention, the movement instruction is accepted by selecting and operating a thin line camera icon which is a fixed point (monitoring point registration position) on the rail map image (route image). The monitor can specify the position of a fixed point, which is a desired monitoring point, while confirming the position on the rail map image (route image). Therefore, the operability of the movement instruction in the viewing PC 6 that is a monitoring device can be improved. .

  Further, according to the embodiment of the present invention, the supervisor confirms the fixed point that is the unnecessary monitoring point registration position, and the position of the unnecessary fixed point (monitoring point) on the rail map image (route image). Since these can be deleted while changing, these fixed points (monitoring points) can be easily changed.

  Further, according to the embodiment of the present invention, by setting a predetermined interval of the count mark 207 as a mark in accordance with the required position accuracy, it is possible to construct a position specifying means with desired accuracy with a simple configuration. In addition, since only the count mark 207, which is a sign, is provided on the moving rail 200 serving as the moving path, the moving rail 200 does not require rewriting of data or the like when using a non-contact IC tag or the like. The rail 200 (movement path) can be easily reused.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the above-described embodiment, the moving rail 200 with the count marks 207 attached at predetermined intervals is used, and the count marks 207 are counted to the count number (distance) of the count marks 207 from the home position as the reference position. However, the present invention is not limited to this. For example, instead of the count mark 207, the present invention is not limited to this. Using non-contact IC tags storing coordinate data and count mark IDs, position coordinate data and count mark IDs are received from these non-contact IC tags to identify the current position, or for position specification Multiple transmitter stations that transmit radio waves are provided, and the position is determined from the arrival time of radio waves from these transmitter stations, or laser light is specified And fired positions may be specified position from the arrival time of the reflected laser light.

  In the embodiment, the fixed point (registered position) that is a monitoring point is displayed on the rail map, and the selection of the fixed point (registered position) that is the monitored point is accepted on the rail map. The invention is not limited to this, and fixed points (registered positions) as these monitoring points are not displayed on the rail map but as menu buttons such as “registered position 1” and “registered position 2” on the main menu screen. You may make it display and accept selection.

  Moreover, in the said Example, although a rail map is displayed with a monitoring image, this invention is not limited to this, You may make it not display these rail maps.

  In the above-described embodiment, a fixed point (registered position) as a monitoring point is selected on the rail map, and the selected fixed point (registered position) can be deleted. However, the present invention is not limited to this. However, these deletions may be deleted only by specific observers. Furthermore, the fixed points (registered positions) that are the monitoring points can be selected other than the selection on the rail map. You may make it accept according to direction.

  In the above embodiment, in order to use the commercially available Web camera 110, the control PC 100 is mounted on the mobile terminal 1 separately from the control microcomputer provided in the Web camera 110. The present invention is not limited to this, and the control PC 100 may execute the control processing of the Web camera 110 that is executed by the control microcomputer by integrating the control microcomputer and the control PC 100.

It is a system configuration figure showing the whole picture of the monitoring system of the specific field in the example of the present invention. It is an external appearance perspective view which shows the mobile terminal and moving rail in the Example of this invention. It is a side view which shows the detail of the movement rail in the Example of this invention. (A)-(c) is a figure which shows the structure of the mobile terminal used for the Example of this invention. It is a figure which shows transmission / reception of the information between the Web camera used for the Example of this invention, and control PC. It is a figure which shows transfer of the information between PC for managers used for the Example of this invention, and control PC. (A) is a figure which shows the list of the data memorize | stored in the memory | storage part of control PC, (b) is a figure which shows status data, (c) is a figure which shows PTZ information, (d) is a figure. It is a figure which shows fixed point data. (A) is a figure which shows the header which comprises rail map data, (b) is a figure which shows a count mark list, (c) is a figure which shows an example of a count mark list. It is a figure which shows the processing condition of control PC based on the detection of a home detection sensor. It is a figure which shows the processing condition of control PC based on the detection of an end detection sensor. It is a figure which shows the processing condition of control PC based on the detection of a count sensor. It is a figure which shows the processing condition of control PC based on the detection of a preset sensor. It is a figure which shows the processing condition of control PC based on a timer interruption. It is a figure which shows the process condition of the control PC based on operation from PC for browsing, mainly the process before operation reception. It is a figure which shows the process condition of the control PC based on operation from PC for browsing, mainly the process after operation reception. It is a figure which shows the authentication page which a control PC delivers to browsing PC. It is a figure which shows the main page which control PC delivers to browsing PC. (A) is a figure which shows the schedule list | wrist which comprises the monitoring schedule data memorize | stored in the memory | storage part of control PC, (b) is a figure which shows the header which comprises each monitoring schedule, (c) is a fixed point. It is a figure which shows a list | wrist, (d) is a figure which shows an example of each monitoring schedule. It is a figure which shows the processing condition of the control PC based on operation from PC for browsing, mainly automatic monitoring. It is a figure which shows an example of the arrangement | positioning condition of the detection piece and mark to a unit rail.

Explanation of symbols

1 Mobile terminal 2 Wireless LAN transceiver 3 Administrator PC
4 Router 5 Internet 6 Browsing PC
10 Monitoring device 11 Moving cart 100 Control PC
110 Web camera 130 Motor driver unit 152 Home detection sensor 153 End detection sensor 154 Count sensor 155 Preset sensor 204 Home detection piece 205 End detection piece 207 Count mark 208 Preset mark

Claims (5)

An imaging device for capturing an image of a specific area to be monitored; a communication means for transmitting an image captured by the imaging apparatus to a monitoring device provided outside the specific area; A monitoring terminal, comprising: a moving carriage device that moves on a moving route installed in the area; and a control unit that controls movement by the moving carriage apparatus, the moving carriage apparatus being movable within a specific area; ,
The monitoring terminal is connected so as to be capable of data communication through the communication means, transmits movement information based on a movement instruction received from a monitor to the monitoring terminal, and is imaged by the imaging device transmitted from the monitoring terminal. A monitoring device capable of receiving at least monitoring information including an image of the specific area and displaying at least an image of the specific area included in the monitoring information;
And the control means controls the movement by the mobile carriage device based on the movement information transmitted from the monitoring device, so that the specific area where the monitoring terminal is installed is In a monitoring system in a specific area that can be remotely monitored by remotely operating the movement of the monitoring terminal,
The monitoring terminal is
Position specifying means for specifying a current position on the moving route of the mobile carriage device;
Monitoring that stores monitoring point information including a position on the moving route at that time specified by the position specifying means in response to reception of a registration request transmitted based on a registration operation of a monitor in the monitoring device Point information storage means;
The control means includes a monitoring point stored in the monitoring point information storage unit based on reception of a monitoring point movement request transmitted from the monitoring device based on a predetermined operation of the monitoring person in the monitoring device. A monitoring system for a specific area, characterized in that a position included in the information is specified and control is performed to move the mobile carriage device to the specified position. The monitoring terminal is
A route information storage unit for storing route information capable of generating a route image of the travel route;
Route information transmitting means for transmitting the route information stored in the route information storage unit to the monitoring device;
Current position information transmitting means for transmitting current position information capable of specifying the current position specified by the position specifying means to the monitoring device;
Monitoring point information transmitting means for transmitting the monitoring point information stored in the monitoring point information storage means to the monitoring device;
With
The monitoring device is an area corresponding to a current position specified from current position information transmitted from the current position information transmission unit on a route image generated from the route information transmitted from the route information transmission unit. And the identified area can be identified as the current position of the monitoring terminal, and the area corresponding to the position included in the monitoring point information transmitted from the monitoring point information transmitting means is identified and identified. The route image that can be identified as the monitoring point registration position is generated, and the generated route image is displayed together with the image of the specific region included in the monitoring information received from the monitoring terminal. The specific area monitoring system described.   The monitoring device displays the monitoring point registration position in the route image so as to be selectable, and receives a movement instruction from a monitor by a selection operation of the monitoring point registration position on the route image. Item 3. The specific area monitoring system according to Item 2. The monitoring device displays the monitoring point registration position in the route image so that the selection operation can be performed, and receives a deletion instruction from the monitor by a selection operation of the monitoring point registration position on the route image and a predetermined deletion operation. , Sending a request to delete the selected monitoring point registration position to the monitoring terminal,
4. The monitoring terminal deletes the monitoring point information of the selected monitoring point registration position stored in the monitoring point information storage unit based on the reception of the deletion request. A monitoring system for a specific area as described in 1.   The position specifying means includes a sign detection unit that detects signs provided at predetermined intervals on the movement route, and the sign detection unit counts the number of signs from a reference position on the movement route, thereby moving the movement. The specific position monitoring system according to claim 1, wherein a current position on the route is specified.

Images