JP2017046141A - Design device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a design device which can easily perform the design and the supervision of a meter reading network.SOLUTION: A CPU in a tablet displays, on a touch panel 4, marks M1-M28 which indicate the position of radio equipment input to a map. After a designer performs the touch selection of the marks M1-M28 to select GW radio equipment and meter radio equipment which configure the meter reading network, and when the designer performs a touch operation to a network registration icon, the CPU sets the selected meter radio equipment to be the GW radio equipment and the radio equipment, to grant a network number thereto.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a design device, and more particularly to a meter reading network design device.

  Conventionally, it is composed of a GW (gateway) radio and a plurality of meter radios connected to the meter, and the meter radio transmits the meter reading value directly or via another meter radio to GW radio. A meter reading network that transmits data to a machine is known (Patent Document 1). And a handy terminal terminal (HHT) can collect a meter collectively by receiving a plurality of meter-reading values from a GW radio.

  In performing batch meter reading using the meter reading network described above, the administrator selects a GW wireless device and meter wireless device from among the wireless devices arranged at each customer's home in advance, designs the meter reading network, and each meter reading It is necessary to assign a network number to each network for management. However, there has been a problem that a design method for the meter reading network has not been established.

JP 2012-28966 A

  Accordingly, an object of the present invention is to provide a design apparatus that can easily design and manage a meter reading network.

  The invention according to claim 1 made to solve the above-described problem is composed of a GW radio and a meter radio connected to the meter, and the meter radio directly reads the meter reading value of the meter. Or a design device used to design a meter reading network that relays to another GW radio and transmits it to the GW radio, the input device inputting the position of the radio, and input by the input means GW setting means for setting one of a plurality of wireless devices as the GW wireless device, meter wireless device setting means for setting the meter wireless device from among the plurality of wireless devices input by the input means, Network identification information attaching means for automatically assigning network identification information to a meter-reading network constituted by the set GW radio and the meter radio; And network identification information, a design apparatus characterized by comprising: a metering network corresponding to the network identification information, and a recording means for recording in association with.

  The invention according to claim 2 is a display control means for displaying a mark indicating the position of the input radio on a map, and a GW selection means for selecting the GW radio from the input radio. A meter radio selection means for selecting the meter radio from the input radio, and a setting operation means for performing a setting operation for setting the GW radio and the meter radio. The display control means displays the mark so that it can be identified that the radio is selected as the GW radio, and can identify that the radio is selected as the meter radio. The mark is displayed, and the GW setting unit and the meter radio setting unit are selected by the GW selection unit and the meter radio selection unit according to the operation of the setting operation unit. A design device according to claim 1, characterized in that to set the radio as the GW radios and the meter radio.

  According to a third aspect of the present invention, after the GW radio is selected, first determination means for determining a radio that can directly communicate with the selected GW radio based on a position of the radio. Second determination means for determining a radio that can communicate with the selected GW radio by relay based on the position of the radio, and the meter radio selection means includes the first determination means by the first determination means. It is prohibited to select, as the meter radio, a radio that is not determined to be directly communicable with a GW radio and that is not determined to be communicable with the GW radio by relay by the second determination unit. The design apparatus according to claim 2.

  The invention according to claim 4 is a first determination means for determining a radio that can directly communicate with the selected GW radio based on the position of the radio after the GW radio is selected; Second determination means for determining a radio that can communicate with the selected GW radio by relay based on the position of the radio, and the display control means before the meter radio is selected The design apparatus according to claim 2, wherein the wireless device is displayed so that it can be visually recognized that the wireless device can communicate with the selected GW wireless device directly or by relay.

  As described above, according to the first aspect of the present invention, when the GW radio and the meter radio are set, the network identification information setting means is a meter reading composed of the set GW radio and the meter radio. Network identification information is automatically assigned to the network, and the recording means records the network identification information and the meter reading network corresponding to the network identification information in association with each other. Thus, when the meter reading network is set, the network identification information can be automatically assigned and the network identification information can be managed (recorded), and the meter reading network can be easily designed.

  According to invention of Claim 2, the position on the map of the selected GW radio and meter radio | wireless machine can be confirmed easily.

  According to the third aspect of the present invention, a device that cannot communicate with the selected GW radio is not selected as a meter radio.

  According to the fourth aspect of the present invention, since it is possible to visually recognize that the radio before being selected as the meter radio is a radio that can communicate with the selected GW radio directly or by relay, Easy to choose.

It is a block diagram which shows one Embodiment of the tablet as a design apparatus of this invention. It is explanatory drawing for demonstrating the meter-reading network designed with the tablet shown in FIG. It is a figure which shows the example of a display of the touch panel shown in FIG. 1 before meter-reading network design. It is a figure which shows the example of a display of the touch panel shown in FIG. 1 when the mark M6 is selected as a GW radio. It is a figure which shows the example of a display of the touch panel shown in FIG. 1 when the mark M6 is selected as a GW radio, and the marks M5 and M7 are selected as a meter radio. It is a figure which shows the example of a display of the touch panel shown in FIG. 1 when the mark M6 is selected as a GW radio and mark M4, M5, and M7-M10 are selected as a meter radio. It is a figure which shows the example of a display of the touch panel shown in FIG. 1 when the mark M6 is selected as a GW radio, and the marks M1-M5 and M7-M10 are selected as a meter radio. It is a figure which shows the table recorded in RAM shown in FIG. It is a figure which shows the example of a display of a touchscreen when registering a new network. It is explanatory drawing for demonstrating the meter-reading network set when registration is completed about all the marks.

(First embodiment)
Hereinafter, a tablet as a design apparatus of the present invention in a first embodiment will be described with reference to FIGS. A design app for designing the meter reading network shown in FIG. 2 is installed in the tablet 1 shown in FIG. Before describing the configuration of the tablet 1, the meter reading network will be described with reference to FIG.

  As shown in the figure, the meter reading network N includes a GW (gateway) wireless device 11 and a plurality of meter wireless devices 13a to 13d connected to the meters 12a to 12d, and the meter wireless devices 13a to 13d are connected to each other. In this network, the meter reading values of the meters 12a to 12d are transmitted to the GW wireless device 11 directly or via other meter wireless devices 13a to 13d. The meters 12a to 12d are meters that are installed in customer's homes and measure water, gas, electricity, and the like. In the example shown in FIG. 2, the meter 14 is also connected to the GW radio 11, but the meter 14 may not be connected to the GW radio 11.

  In the example illustrated in FIG. 2, the meter wireless devices 13 a and 13 b can directly transmit the meter reading values of the meters 12 a and 12 b to the GW wireless device 11. The meter wireless device 13c can transmit the meter reading value of the meter 12c to the GW wireless device 11 by relaying the other meter wireless devices 13a, 13b, and 13d. The meter wireless device 13d can transmit the meter reading value of the meter 12d to the GW wireless device 11 by relaying the other meter wireless devices 13a to 13c.

  When the GW wireless device 11 wirelessly receives a meter reading request from the tablet 1, in addition to the meter reading value of the meter 14 connected to the GW wireless device 11, the meters 12 a to 12 d transmitted from the other meter wireless devices 13 a to 13 d. The meter reading value is transmitted to the tablet 1. Thereby, the tablet 1 can perform the meter-reading of the meters 14 and 12a-12d only by carrying out wireless communication with the GW radio | wireless machine 11. FIG.

  It is considered that a plurality of meter reading networks N described above are provided throughout the country so that collective meter reading can be performed in various places. For this reason, the administrator designs the meter reading network N by selecting the GW wireless device 11 and the meter wireless devices 13a to 13d from the wireless devices arranged in each customer's home in advance, and overlaps with each meter reading network N. It is necessary to manage by attaching a network number (= network identification information) so that it does not occur.

  The design application input to the tablet 1 of the present embodiment is an application for designing the meter reading network N and managing the designed meter reading network N by assigning a network number.

  Next, the configuration of the tablet 1 will be described. As shown in FIG. 1, the tablet 1 includes a microcomputer 2 (hereinafter referred to as a microcomputer 2) that controls the entire tablet 1, a wireless communication unit 3, and a touch panel 4 that is controlled by the microcomputer 2.

  The microcomputer 2 includes a CPU 2A that performs various processes according to a processing program, a ROM 2B that stores a program for processes performed by the CPU 2A, and a RAM 2C that can be overwritten.

  The wireless communication unit 3 is a known wireless device that can be connected to a wireless communication network or the like. The tablet 1 uses this wireless communication unit 3 to connect to a server (external memory) via a wireless communication network, and receives and inputs a customer list stored in the server wirelessly, or the meter reading value of each meter Can be sent to the server. The customer list is a list of customer names, addresses (positions), etc., where the wireless devices are installed. The touch panel 4 is, for example, a well-known touch panel configured from a display provided with a touch sensor.

  Next, the operation of the tablet 1 having the above-described configuration will be described with reference to FIGS. The CPU 2 </ b> A of the tablet 1 starts up a network design application in response to an operation on the touch panel 4. Thereafter, the CPU 2A functions as an input means, and connects to the server using the wireless communication unit 3 in accordance with the operation of the touch panel 4, receives the customer list, and inputs it to the RAM 2C.

  Next, when the designer touches, for example, a new design icon (not shown) displayed on the touch panel 4, the CPU 2A functions as a display control unit as shown in FIG. An image in which marks M1 to M28 indicating the position (address) where the machine is installed is superimposed is displayed on the touch panel 4. In an initial state that does not belong to any meter reading network, the marks M1 to M28 are displayed in gray, for example.

  First, the designer touches one of the marks M1 to M28 displayed in gray on the touch panel 4 to select the GW radio. The CPU 2A displays the marks M1 to M28 touched as the GW radio from gray to green. For example, when the designer touches the mark M6, as shown in FIG. 4, the mark M6 is displayed in green, for example, to indicate that it has been selected as a GW radio. As is clear from this, the CPU 2A functions as a GW selection unit.

  Thereafter, when the designer operates, for example, a GW selection icon (not shown) displayed on the touch panel 4, the CPU 2A displays the characters “Cancel” and “OK” on the touch panel 4. Superimposed display.

  When the designer touches “Cancel”, the CPU 2A erases the characters “Cancel this customer”, “Cancel”, and “OK”, and returns to the display shown in FIG.

  On the other hand, when the designer touches “OK”, the CPU 2A next displays the characters “Please select a customer to be associated with the GW” and “OK”. When the designer touches “OK”, the CPU 2A deletes the characters “Please select a customer to be associated with GW” and “OK” and returns to the display shown in FIG.

  Note that the circle shown in FIG. 4 or the circle shown in FIGS. 5 to 10 below is the line-of-sight distance of the wireless device and is described for easy understanding of the description. However, in the first embodiment, the circle is shown. There is no indication.

  Further, the CPU 2A functions as a first determination unit, determines a wireless device that can directly communicate with the selected GW wireless device, and stores it in the RAM 2C. For example, the CPU 2 </ b> A determines that a wireless device within the line-of-sight distance that considers the performance of the wireless device is a wireless device that can directly communicate with the selected GW wireless device. For example, as shown in FIG. 4, when the mark M6 is set as a GW radio, the marks M5 and M7 within the line-of-sight distance R6 of the mark M6 are determined as radios capable of direct communication.

  Next, the designer touches the marks M1 to M5 and M7 to M28 displayed in gray on the touch panel 4 to select them as meter radios. When the directly communicable marks M5 and M7 stored in the RAM 2C are touched, the CPU 2A changes the color from gray to blue, for example, and identifies that it is selected as a meter radio as shown in FIG. to enable. On the other hand, even if the marks M1 to M4 and M8 to M28 other than the marks M5 and M7 are touched, the CPU 2A prohibits selection as a meter wireless device while remaining gray. As is clear from this, the CPU 2A functions as a meter radio selection unit.

  When the mark M5 or M7 is touched and selected as a meter radio, the CPU 2A functions as a second determination unit, determines a radio that can communicate with the selected GW radio by relay, and stores it in the RAM 2C. Remember. For example, the CPU 2 </ b> A determines a wireless device within the line-of-sight distance centered on the selected meter wireless device as a wireless device that can communicate by relay. For example, as shown in FIG. 5, when the mark M5 is selected as the meter radio, the mark M4 within the line-of-sight distance R5 is determined as a radio that can communicate by relay. When the mark M7 is selected as the meter radio, the marks M8 to M10 within the line-of-sight distance R7 are determined as radios that can communicate by relay.

  Subsequently, the designer touches the marks M1 to M4 and M8 to M28 displayed in gray on the touch panel 4 to select them as meter radios. When the marks M5 and M7 are selected as meter radios, the CPU 2A changes the color from gray to blue, for example, as shown in FIG. 6, when the marks M4 and M8 to M10 that can be communicated by relay are touched. Thus, it is possible to identify that it has been selected as the meter radio. On the other hand, even if the marks M1 to M3 and M11 to M28 other than the marks M4 and M8 to M10 are touched, the CPU 2A prohibits selection as a meter wireless device while remaining gray.

  Each time the CPU 2A selects a meter radio, the CPU 2A determines that the radio within the line-of-sight distance centered on the selected meter radio is a radio that can communicate by relay, so that it can be selected as a meter radio. To do. As a result of repeating this, as shown in FIG. 7, when the marks M1 to M5 and M7 to M10 are selected as meter radios for the mark M6 that is a GW radio, there are no marks that can be selected as meter radios.

  Next, when the selection of the meter radio is completed, the designer touches a network registration icon (not shown) displayed on the touch panel 4. When the touch operation of the network registration icon is performed, the CPU 2A functions as a GW setting unit, and the wireless device selected as the GW wireless device, that is, the wireless device corresponding to the mark M6 displayed in green shown in FIG. 7 is used as the GW wireless device. Set. Further, the CPU 2A functions as a meter radio setting unit, and the radios corresponding to the marks M1 to M5 and M7 to M10 displayed in blue shown in FIG. 6 are selected as meter radios. Set. As is clear from the above, the touch panel 4 functions as setting operation means.

  Next, the CPU 2A functions as a network identification information adding unit, and the network number (indicated by a dotted line in FIG. 7 is used as a network number (mark M6 is a GW radio, and marks M1 to M5 and M7 to M10 are meter radios). Network identification information) and channel number are automatically assigned. Further, the CPU 2A assigns a radio number to the radios corresponding to the marks M1 to M10 constituting the meter-reading network N1.

  Then, the CPU 2A functions as a recording unit, and as shown in FIG. 8, the network number, the channel number, the customer name, the customer address, and the wireless device number of the wireless device constituting the meter-reading network N1 corresponding to the network number, An associated table is created and stored in the RAM 2C. Next, the designer touches a transmission icon (not shown) displayed on the touch panel 4. Then, the CPU 2A connects to the server via the wireless communication network by the wireless communication unit 3, and transmits the table to the server.

  Thereafter, when the designer touches a new setting icon (not shown) displayed on the touch panel 4 again, the CPU 2A, as shown in FIG. 9, displays the position where the radio device input on the map is installed ( An image in which marks M1 to M28 (marks) indicating (address) are superimposed is displayed on the touch panel 4. At this time, marks M1 to M10 indicating the wireless devices constituting the already set meter reading network N1 are displayed in orange, and marks M11 to M28 indicating wireless devices that do not belong to any meter reading network are displayed in gray. .

  Then, as described above, the meter reading network is designed by setting the GW radio and the meter radio in the same procedure. As a result, in the example shown in FIG. 10, in addition to the meter reading network N1, the meter reading network N2 with the mark M11 as the GW radio, the marks M12 and M13 as the meter radio, the mark M14 as the GW radio, and the mark M15 as the meter radio Meter reading network N3, mark M21 as a GW radio, marks M16 to M20 and M22 to M24 as meter radios, meter reading network N4, mark M26 as a GW radio, and marks M25, M27, and M28 as meter radios A meter reading network N5 is set.

  Similarly, when the meter reading networks N1 to N5 are designed, the CPU 2A assigns a network number, a channel number, and a radio number. At this time, the CPU 2A does not assign the already assigned network number, and assigns the network numbers in order from 1, for example, so as not to overlap.

  Further, for example, if the same channel number is given to the meter reading networks N1 and N2 adjacent to each other, the meter reading value from the meter wireless device constituting the meter reading network N2 is transmitted to the GW wireless device of the meter reading network N1, which is useless. Communication may occur, and it may take time to transmit the meter reading.

  Therefore, the CPU 2A prevents the same channel number from being assigned to the adjacent meter-reading network. For example, in the example shown in FIG. 10, the CPU 2A assigns different channel numbers to adjacent meter reading networks N1 to N4. The meter reading networks N1 and N5 that are not adjacent may be assigned the same channel number.

  According to the first embodiment described above, when the GW radio and the meter radio are set, the CPU 2A assigns a network number to the meter reading network constituted by the automatically set GW radio and meter radio. Then, the table shown in FIG. 8 in which the network number is associated with the meter reading network corresponding to the network number is recorded in the RAM 2C. Thereby, when the meter reading network is set, the assignment of the network number and the management (recording) of the network number can be automatically performed, and the meter reading network can be designed easily.

  Further, according to the first embodiment described above, the CPU 2A changes the display color of the marks M1 to M28 from gray to green so that it can be identified as the wireless device selected as the GW wireless device, and displays it. The display colors of the marks M1 to M28 are changed from gray to blue so that the radio can be identified as the meter radio. Thereby, the positions on the map of the selected GW radio and meter radio can be easily confirmed.

  Further, according to the first embodiment described above, when the CPU 2A selects the marks M1 to M28 by touch, if the radio is not capable of communicating directly or via a relay with the selected GW radio, it is selected as gray. Is prohibited. As a result, a device that cannot communicate with the selected GW radio is not selected as a meter radio.

(Second embodiment)
Next, the tablet 1 in 2nd Embodiment is demonstrated. In the first embodiment, if the tablet 1 is not a wireless device that can communicate with the selected GW wireless device directly or via a relay, even if the marks M1 to M28 are touch-selected, the tablet 1 remains gray and can be changed to blue. I tried not to do this, but it is not limited to this.

  For example, after the GW radio is selected as the mark M6 and before the meter radio is selected, as shown in FIG. 5, the CPU 2A sets the marks M5 and M7 of the radio that can communicate with the mark M6, for example. It may be displayed in yellow so that it can be visually confirmed that communication with the mark M6 is possible. The designer can select a meter radio by touching the marks M5 and M7 displayed in yellow. At this time, the marks M5 and M7 that have been touch-selected as meter radios change the display color from yellow to blue to indicate that they are selected as meter radios. In this case, since it is known whether or not communication with the GW radio can be performed before touch selection, the designer can easily select the meter radio.

  In the second embodiment, the display color of the marks M1 to M28 can be identified as being communicable with the GW radio. However, the present invention is not limited to this. It may be possible to identify that communication with the mark M6 selected as the GW radio is possible by actually superimposing and displaying a circle indicating the line-of-sight distance R6 in FIG.

  In the first and second embodiments described above, the CPU 2A determines the wireless device that can communicate with the GW wireless device based on only the line-of-sight distance of the wireless device. However, the present invention is not limited to this. For example, when there is a shield such as a high building that blocks radio waves from a radio, the position of the shield can be input to the tablet 1 in advance, and the CPU 2A considers the position of the input shield. Then, a wireless device that can communicate with the GW wireless device may be determined.

  Further, according to the first and second embodiments described above, the designer selects and sets the meter radio, but the present invention is not limited to this. For example, after the GW radio is selected by the designer, the CPU 2A determines a radio that can directly communicate with the selected GW radio, and automatically selects the determined radio as a meter radio. May be. Further, the CPU 2A determines a wireless device that can communicate with the GW wireless device by relaying the wireless device automatically selected as the meter wireless device, and further automatically selects the determined wireless device as the meter wireless device. Also good. However, since the number of meter radios constituting the meter-reading network is limited, the CPU 2A automatically selects the meter radio so that the number limit is not exceeded.

  Further, according to the first and second embodiments described above, the GW radio is selected and set by the designer, but the present invention is not limited to this. For example, the CPU 2A may automatically set the GW radio when a customer list is input. For example, the CPU 2A may automatically set the distance based on the distance from the management office or the positional relationship between the wireless devices.

  Further, according to the first and second embodiments described above, when the marks M1 to M28 of the wireless devices that can communicate with the GW wireless device directly or by relay are touched, the display color of the marks M1 to M28 is changed from gray to green. However, this is not limited to this. For example, the colors of the marks M1 to M28 are changed depending on whether there is a margin and good radio communication can be expected with respect to the line-of-sight distance of the GW radio, and there is a possibility that the radio communication may be slightly uneasy because there is no margin. You may make it display these so that identification is possible.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

1 tablet (design device)
2A CPU (input means, GW setting means, meter radio setting means, network identification information giving means, recording means, display control means, GW selection means, meter radio selection means, first determination means, second determination means)
4 Touch panel (setting operation means)
11 GW radio 12a-12d meter 13a-13d meter radio M1-M28 mark N meter-reading network

Claims (4)

A meter reading device comprising a GW wireless device and a meter wireless device connected to the meter, wherein the meter wireless device transmits the meter reading value of the meter directly or through another meter wireless device to the GW wireless device. A design device used to design a network,
Input means for inputting the position of the radio;
GW setting means for setting one of a plurality of radios input by the input means as the GW radio;
Meter radio setting means for setting the meter radio from a plurality of radios input by the input means;
Network identification information giving means for automatically giving network identification information to the meter reading network configured from the set GW radio and the meter radio;
A design apparatus comprising: recording means for associating and recording the network identification information and a meter-reading network corresponding to the network identification information. Display control means for displaying a mark indicating the position of the input wireless device on a map;
GW selection means for selecting the GW radio from the input radios;
Meter radio selection means for selecting the meter radio from the input radio;
A setting operation means for performing a setting operation for setting the GW radio and the meter radio,
The display control means displays the mark so that it can be identified that the radio is selected as the GW radio, and also identifies the radio selected as the meter radio. Mark is displayed,
The GW setting unit and the meter radio setting unit use the radio selected by the GW selection unit and the meter radio selection unit according to the operation of the setting operation unit as the GW radio and the meter radio. The design device according to claim 1, wherein the design device is set. After the GW radio is selected, first determination means for determining a radio that can directly communicate with the selected GW radio based on the position of the radio;
Second determination means for determining a radio that can communicate with the selected GW radio by relay based on a position of the radio,
The meter radio selecting unit is a radio that is not determined to be directly communicable with the GW radio by the first determining unit and is not determined to be communicable with the GW radio by the second determining unit. The design apparatus according to claim 2, wherein selection as the meter radio is prohibited. After the GW radio is selected, first determination means for determining a radio that can directly communicate with the selected GW radio based on the position of the radio;
Second determination means for determining a radio that can communicate with the selected GW radio by relay based on a position of the radio,
The display control means displays the radio before being selected as the meter radio so that it can be visually recognized that the radio can be communicated with the selected GW radio directly or by relay. The design apparatus according to claim 2.

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