JP7062977B2 - How to group multiple wireless devices - Google Patents

Description

The present invention relates to a method of grouping a plurality of wireless devices.

A method of pairing the master unit and the slave unit by reading the QR code (registered trademark) displayed on the master unit into the master unit and the slave unit (operation terminal) of the air conditioning control system in the entire building. Is known (for example, Patent Document 1).

JP-A-2015-126396

However, in the method of Patent Document 1, since the slave unit is brought near the master unit and the QR code is read by the slave unit, it is troublesome and inconvenient especially when the number of slave units is large. .. On the other hand, it is conceivable to automatically pair using wirelessly, but if the same system is used in different buildings for air conditioning, the master unit and the slave units of other systems are mistakenly paired. There was a problem of being ringed. These issues are solved when the same air conditioning system is installed in multiple large buildings, the number of slave units is large, and the distance between the master unit and the slave unit in one building varies greatly. This is likely to occur if the aircraft is not in the center of the building.

The present invention has been made to solve a part of the above-mentioned problems, and can be realized as the following forms.

(1) According to one embodiment of the present invention, there is provided a grouping method for grouping a master unit of a wireless system arranged in a building and a plurality of wireless devices including a plurality of slave units. This grouping method includes (a) a step of executing communication between the plurality of wireless devices and acquiring communication time and communication strength in a combination of the two wireless devices, and (b) the communication time and the communication. It includes a step of identifying a wireless device that deviates from the correlation with the strength, and (c) a step of grouping the plurality of slave units excluding the specified wireless device. Generally, the outer wall of a building has a heavier structure than the partition inside the building. Therefore, in the communication between the wireless device located inside the outer wall of the building and the wireless device located outside the outer wall of the building, the communication strength is significantly higher than the communication between the wireless devices located inside the building. Decays to. In communication between wireless devices located inside the building, if there is a correlation between communication time and communication strength, the wireless device located inside the outer wall of the building and the wireless device located outside the outer wall of the building Communication with will deviate from this correlation. According to this form, it can be determined that the wireless devices that deviate from the correlation between the communication time and the communication strength do not exist in the building, so that only the wireless devices existing in the building can be grouped.

(2) In the above embodiment, the step (b) includes (b1) a step of detecting a combination of the two wireless devices having the shortest communication time and selecting the two wireless devices as a group, and (b2). The shortest combination of the communication time between the wireless device included in the group and the wireless device not included in the group is detected, and the wireless device not included in the group among the two wireless devices forming the combination is detected. Is added to the group to select a new group having one more wireless device, a step of repeating (b3) step (b2), and a step of (b4) steps (b1) to (b3) are obtained in order. Each time the group is obtained, the step of calculating the correlation coefficient using the communication time and the communication strength as two parameters, and (b5) the radio using the correlation coefficient to deviate from the correlation. It may include a step of identifying the device. According to this form, the correlation coefficient between the communication time and the communication strength is calculated for the groups obtained in order, and the correlation coefficient is used between the wireless device existing in the building and the wireless device not existing in the building. In order to identify the wireless device, it is possible to reduce the amount of calculation for identifying the wireless device existing in the building and the wireless device not existing in the building, rather than calculating the correlation coefficient by round-robin.

(3) In the above embodiment, the step (b) includes (b1) a step of detecting a combination of the two wireless devices having the strongest communication strength and selecting the two wireless devices as a group, and (b2). The strongest combination of the communication strength between the wireless device included in the group and the wireless device not included in the group is detected, and the wireless device not included in the group among the two wireless devices forming the combination is detected. Is added to the group to select a new group having one more wireless device, a step of repeating (b3) step (b2), and a step of (b4) steps (b1) to (b3) are obtained in order. Each time the group is obtained, the step of calculating the correlation coefficient using the communication time and the communication strength as two parameters, and (b5) the radio using the correlation coefficient to deviate from the correlation. It may include a step of identifying the device. According to this form, the correlation coefficient between the communication time and the communication strength is calculated for the groups obtained in order, and the correlation coefficient is used between the wireless device existing in the building and the wireless device not existing in the building. In order to identify the wireless device, it is possible to reduce the amount of calculation for identifying the wireless device existing in the building and the wireless device not existing in the building, rather than calculating the correlation coefficient by round-robin.

(4) In the above embodiment, the step (b) is (b1) a step of calculating a regression equation showing the relationship between the communication time and the communication strength, and (b2) a step of calculating a confidence interval for the regression equation. And (b3) a step of identifying a radio device that deviates from the correlation by using the confidence interval may be included. According to this form, since the regression equation showing the relationship between the communication time and the communication strength and the confidence interval thereof are used, the wireless device deviating from the correlation can be easily identified.

(5) In the above embodiment, the step (b1) may include a step of recalculating the regression equation by robust estimation. According to this form, the influence of the communication time with the wireless device and the communication strength on the regression equation can be reduced, so that the correlation between the communication time and the communication strength deviates greatly. It is possible to more accurately identify the wireless device to be used.

The present invention can be realized in various forms, for example, in the form of a wireless system including a plurality of wireless devices, in addition to a method of grouping a plurality of wireless devices.

It is explanatory drawing which shows the positional relationship between the master unit of the air conditioning control system in 1st Embodiment, and a plurality of slave units. It is a timing chart of the process of acquiring the communication time and communication strength between a master unit and each slave unit. It is a timing chart of the process of acquiring the communication time and communication strength between a master unit and another slave unit with reference to the slave unit. It is a timing chart of the process of acquiring the communication time and communication strength between a master unit and another slave unit with respect to another slave unit with reference to another slave unit. It is explanatory drawing which shows an example of the measured value of communication time and communication strength. It is explanatory drawing which shows an example of the grouping procedure. It is explanatory drawing which plotted communication time and communication strength in order. It is explanatory drawing which plotted the communication time and communication strength in the comparative example. It is explanatory drawing which shows the master unit and the slave unit of the whole building air-conditioning control system of the adjacent building. It is explanatory drawing which shows the relationship between the communication time and communication strength between a master unit and each slave unit.

-First embodiment:
FIG. 1 is an explanatory diagram showing a positional relationship between a master unit 0 of the air conditioning control system 10 and a plurality of slave units 1 to 4 according to the first embodiment. The air conditioning control system 10 is installed in the building X of the facility, and includes a master unit 0 and slave units 1 to 3. The master unit 0 and the slave units 1 to 3 constitute a wireless system. The master unit 0 is the main body of the air conditioning control system 10, and receives a request by wireless communication from the slave units 1 to 3 to perform air conditioning in each room. The slave units 1 to 3 are arranged in each room, perform wireless communication with the master unit 0, and request the master unit 0 to air-condition each room. The slave unit 4 is a slave unit of an air conditioning control system of the same type as the air conditioning control system 10, and does not exist in the building X. Therefore, there is a wall 30 of the building X between the master unit 0 and the slave unit 4.

In the first embodiment, the master unit 0 and the slave units 1 to 3 are paired, and the master unit 0 and the slave unit 4 are not paired. Pairing means registering pairing information, for example, an ID with each other. Prior to pairing, the master unit 0 acquires the communication time and communication strength between the master unit 0 and each of the slave units 1 to 4. FIG. 2 is a timing chart of processing for acquiring the communication time and communication strength between the master unit 0 and the slave units 1 to 4. In step S100, the master unit 0 transmits a broadcast to the slave units 1 to 4 and requests the device ID. As the frequency of the radio wave used for these communications, for example, a radio wave in the 900 MHz band is used. If the radio wave is in the 900 MHz band, it is not easily affected by obstacles and an appropriate communication distance can be obtained. That is, if the frequency of the radio wave is too high, communication may be difficult due to the influence of obstacles depending on the position of the slave unit in the building X. On the other hand, if the frequency of the radio wave is too low, the communication distance becomes long, and there is a possibility of communicating with the slave unit outside the building X. Therefore, it is appropriate to use radio waves in the 900 MHz band. Note that radio waves other than the 900 MHz band, for example, radio waves in the 2.4 GHz band or 5 GHz band may be used. The slave unit 1 that has received the broadcast transmits its own device ID, for example, "A" to the master unit 0 in step S100. In step S112, the master unit 0 transmits a response request to the slave unit 1. The master unit 0 can specify only the slave unit 1 by including the device ID of the slave unit 1 in the response request. In step S114, the slave unit 1 transmits a reply to the response request to the master unit 0. The master unit 0 acquires the time obtained by subtracting the internal processing time in the slave unit 1 from the time from the response request in step S112 to the reception of the reply in step S114 as the communication time between the master unit 0 and the slave unit 1. .. Further, the communication strength between the master unit 0 and the slave unit 1 is acquired from the strength of the reply received in step S114.

In steps S120, S122, and S124, the master unit 0 and the slave unit 2 perform the same communication as in steps S110, S112, and S114, the communication time between the master unit 0 and the slave unit 2, and the master unit 0 and the child. Acquires the communication strength with the machine 2. Similar communication is performed in steps S130, S132, S134, and steps S140, S142, and S144, and the master unit 0 has the communication time between the master unit 0 and the slave unit 4 and the master unit 0 and the child. The communication strength between the master unit 4 and the communication strength between the master unit 0 and the slave unit 3 and the communication strength between the master unit 0 and the slave unit 3 are acquired. The responses of steps S110, S120, S130, and S140 to the broadcast of step S100 may overlap. In this case, the master unit 0 may execute step S112 after a certain period of time has elapsed after receiving the response to the broadcast, and execute the next S122 after step S114 for step S112 is completed. Similarly, S132 and S142 may be executed in order.

In step S200, the master unit 0 transmits a measurement request message to the slave unit 1. This measurement request message is a message instructing the slave unit 1 to measure the communication time and communication strength between the master unit 0 and the slave units 2 to 4. The slave unit 4 belongs to an air conditioning control system different from that of the master unit 0, but since it is a slave unit of the same type of air conditioning control system as the air conditioning control system 10, it is possible to reply to the broadcast in step S100. There is sex. The slave unit that has already been paired with another master unit may be configured not to reply to the broadcast in step S100. By doing so, since the master unit 0 receives a reply to the broadcast of step S100 only from the slave unit that has not been paired, it is possible to send a measurement request message only to the slave unit that has not been paired. can.

FIG. 3 is a timing chart of processing for acquiring the communication time and communication strength between the master unit 0 and the other slave units 2 to 4 with the slave unit 1 as a reference. In step S212, the slave unit 1 sends a response request by designating the ID (0) of the master unit 0, and in step S214, the master unit 0 transmits a reply to the response request to the slave unit 1. .. The slave unit 1 acquires the time obtained by subtracting the internal processing time of the master unit 0 from the time from the response request in step S212 to the reception of the reply in step S214 as the communication time between the slave unit 1 and the master unit 0. .. Further, the communication strength between the slave unit 1 and the master unit 0 is acquired from the strength of the reply received in step S214.

Similarly, in steps S222 and S224, the handset 1 acquires the communication time between the handset 1 and the handset 2 and the communication strength between the handset 1 and the handset 2, and steps S232, In S234, the communication time between the handset 1 and the handset 4 and the communication strength between the handset 1 and the handset 4 are acquired, and in steps S242 and S244, the handset 1 and the handset 3 are used. The communication time between the slave units 1 and the communication strength between the slave unit 1 and the slave unit 3 are acquired. In step S250, the slave unit 1 sends a measurement completion message to the master unit 0 together with the communication time and communication strength between the slave unit 1 and the master unit 0, the slave unit 2, the slave unit 3, and the slave unit 4. In step S300, the master unit 0 transmits a measurement request message to the slave unit 2 as in step S200.

FIG. 4 is a timing chart of processing for acquiring the communication time and communication strength between the master unit and the other slave unit with respect to the other slave unit as a reference. In steps S312 to S344, the slave unit 2 communicates with the master unit 0, the slave unit 1, the slave unit 3, and the slave unit 4 in the same manner as in steps S212 to S244 of FIG. 0, the communication time and the communication strength between the slave unit 1, the slave unit 3, and the slave unit 4 are acquired. In step S350, the slave unit 2 sends a measurement completion message to the master unit 0 together with the communication time and communication strength between the slave unit 2 and the master unit 0, the slave unit 1, the slave unit 3, and the slave unit 4. Similarly, the slave unit 3 and the slave unit 4 execute steps S400 to S450 and S500 to S550, respectively. As a result, the master unit 0 obtains the communication time and the communication strength in all combinations between the master unit 0 and the slave units 1 to 4.

FIG. 5 is an explanatory diagram showing an example of measured values of communication time and communication strength. In FIG. 5, there are two measured values, for example, between the master unit 0 and the slave unit 1, there are a value measured and acquired by the master unit 0 and a value measured and acquired by the slave unit 1. Because. In the subsequent processing, the average value of these two measured values is used.

FIG. 6 is an explanatory diagram showing an example of the grouping procedure. First, the combination with the shortest communication time is detected and used as the first group. In the result shown in FIG. 5, since the combination of the master unit 0 and the slave unit 1 has the shortest communication time, the master unit 0 and the slave unit 1 are selected as the first group.

Next, the shortest combination of communication time between the wireless device (master unit 0 or slave unit 1) included in the first group and the wireless device (slave unit 2 to 4) not included in the first group is detected. Then, of the two wireless devices forming the combination, the wireless device not included in the first group is added to the first group, and the wireless device is selected as the second group having one more wireless device. Specifically, the communication time between the master unit 0 and the slave unit 2, the communication time between the master unit 0 and the slave unit 3, the communication time between the master unit 0 and the slave unit 4, and the child. Of the communication time between the handset 1 and the handset 2, the communication time between the handset 1 and the handset 3, and the communication time between the handset 1 and the handset 4, the communication time is the longest. Detect short combinations. In the result shown in FIG. 5, since the combination with the shortest communication time is the combination of the master unit 0 and the slave unit 2, the slave unit 2 is added to the first group, and the master unit 0 and the slave unit 1 are added. And the slave unit 2 are selected as the second group.

Similarly, the combination of the shortest communication time between the wireless device (master unit 0 or slave unit 1, 2) included in the second group and the wireless device (slave unit 3, 4) not included in the first group. Is detected, and the wireless device not included in the second group among the two wireless devices forming the combination is added to the second group and selected as the third group. In the example of FIG. 5, the combination with the shortest communication time is the combination of the slave unit 2 and the slave unit 3. Therefore, the slave unit 3 is added to the second group, and the master unit 0, the slave unit 1, the slave unit 2, and the slave unit 3 are selected as the third group. After that, increase the number of slaves one by one in the same way and repeat new grouping. In this embodiment, since the number of slave units is 4, the grouping is completed in the next 4th group.

As a result of this grouping, each group is as follows.
・ First group: 0 master unit, 1 slave unit
・ Second group: 0 master unit, 1 slave unit, 2 slave units
・ Third group: 0 master unit, 1 slave unit, 2 slave units, 3 slave units
・ Fourth group: 0 master unit, 1 slave unit, 2 slave units, 3 slave units, 4 slave units

Next, the communication time and communication strength when each group is created are plotted, and the correlation coefficient between them is obtained. FIG. 7 is an explanatory diagram in which the communication time and the communication strength are plotted in order. At this time, plotting is performed using the minimum values of communication time and communication strength when each group is created. Specifically, the points corresponding to the point A are plotted from the communication time and communication strength in the combination of the master unit 0 and the slave unit 1 when the first group is selected, and then the parent when the second group is selected. Plot point B from the communication time and communication strength in the combination of machine 0 and handset 2, and then plot point C from the communication time and communication strength in the combination of handset 2 and handset 3 when the third group is selected. Plot. After plotting the three points, the correlation coefficient r1 between the communication time and the communication strength of these three points A, B, and C is obtained. When the absolute value of the correlation coefficient r1 is equal to or greater than a predetermined value, it is said that there is a correlation between these three points, and that the master unit 0 and the slave units 1, 2, and 3 are all in the building X. to decide.

Next, since the minimum value of the communication time when creating the fourth group is obtained by the combination of the handset 1 and the handset 4, it is a point from the communication time and the communication strength corresponding to the combination of the handset 1 and the handset 4. D is plotted and the correlation coefficient r2 is obtained using the communication time and communication strength of the four points A, B, C, and D. When the absolute value of the correlation coefficient r2 is equal to or greater than a predetermined value, there is a correlation between these four points, and the master unit 0 and the slave units 1, 2, 3, and 4 are all in the building X. Judge that there is. On the other hand, when the absolute value of the correlation coefficient r1 is equal to or higher than the predetermined value but the absolute value of the correlation coefficient r2 is less than the predetermined value, it is considered that the correlation has disappeared due to the influence of the slave unit 4. .. That is, the slave unit 4 is a wireless device that deviates from the correlation between the communication time and the communication strength. In this case, it is determined that the master unit 0, the slave units 1, 2, and 3 exist in the building X, and the slave unit 4 does not exist in the building X.

The master unit 0, the slave units 1, 2, and 3 determined to be in the building X are paired using the device ID, and the slave unit 4 is not paired with any of them.

FIG. 8 is an explanatory diagram in which the communication time and the communication strength in the comparative example are plotted. In the comparative example, the slave unit 1 and the slave unit 4 are in the first group, the slave unit 2 is added in the second group, the slave unit 3 is added in the third group, and finally the master unit 0 is added in the fourth group. It is configured. In this case, the correlation coefficient r3 is calculated using the communication time and communication strength of the three points E, F, and G up to the third group, and the four points E, F, G, and H up to the fourth group are calculated. The correlation coefficient r4 is calculated using the communication time and the communication strength of. In this case, since the correlation coefficient between the communication time and the communication strength is less than a predetermined value only when the master unit 0 is included, it is determined that only the master unit 0 does not exist in the building.

As described above, according to the present embodiment, the combination of the two wireless devices having the shortest communication time is detected, the two wireless devices are selected as the first group, and then the wireless devices included in the first group and the wireless devices are selected. The shortest combination of the communication time with the wireless device not included in the first group is detected, and the wireless device not included in the first group among the two wireless devices forming the combination is added to the first group. Select a new second group with one more wireless device. This is repeated to select the third group, the fourth group, and new groups in order. After that, every time a new group is obtained, a correlation coefficient with two parameters of communication time and communication strength is calculated, and the wireless device is built depending on whether the correlation coefficient is more than or less than a predetermined value. Specify whether it exists in X or not in the building X. Therefore, all combinations of 3 or more wireless devices (combination of selecting 3 from 5 wireless devices (combination of 5C3 = 10)), combination of selecting 4 from 5 wireless devices (combination of 5C4 = 5), 5 The calculation time can be shortened compared to finding the correlation coefficient for a combination that selects all wireless devices (combination of 5C5 = 1).

In the first embodiment, when grouping from the first group in order, the grouping is performed in the order of the shortest communication time, but the grouping may be performed in the order of the strongest communication strength.

-Second embodiment:
FIG. 9 is an explanatory diagram showing master units 0 and 20 and slave units 1 to 7 and 21 of the entire building air conditioning control system of adjacent buildings X and Y. The master unit 0 and the slave units 1 to 7 of the air conditioning system are installed in the building X, and the master unit 20 and the slave units 21 of the air conditioning system are installed in the building Y. I want to pair the master unit 0 of the building X with the slave units 1 to 7, and do not pair the master unit 0 of the building X with the slave unit 21 of the building Y. Here, if the air conditioning system installed in the building X and the air conditioning system installed in the building Y are of the same type, the radio waves emitted by the master unit 0 of the building X for pairing are the slave units. There is a possibility that unintended pairing will be performed by communicating not only with 1 to 7 but also with the slave unit 21 of the building Y.

FIG. 10 is an explanatory diagram showing the relationship between the communication time and the communication strength between the master unit 0 and each slave unit. The horizontal axis is the communication time with the master unit 0, and the vertical axis is the communication strength, and the relationship between the distance and the communication strength is plotted. The communication time and communication strength between the master unit 0 and each slave unit can be obtained as described with reference to FIG. 2 of the first embodiment. The master unit 0 calculates a regression equation showing the relationship between the communication time and the communication strength. The regression equation can be obtained, for example, by the method of least squares. FIG. 10 shows a regression line corresponding to the regression equation showing the relationship.

Next, the master unit 0 calculates a confidence interval for the regression equation. As the confidence interval, for example, a 95% confidence interval is used. FIG. 10 shows a 95% confidence interval. The master unit 0 determines that there is no slave unit in the building X corresponding to the plot that deviates from this 95% confidence interval. Generally, there is a wall between the inside of the building X and the outside of the building X that lowers the radio field strength. Therefore, when the vertical axis is the communication strength, the plot corresponding to the slave unit that does not exist in the building X is 95. % It is plotted on the side where the communication strength is weaker than the confidence interval.

As described above, according to the second embodiment, it is possible to specify a wireless device that deviates from the correlation between the communication time and the communication strength by using the regression equation and the confidence interval.

In the second embodiment, in order to reduce the influence of the slave unit that does not exist in the building on the regression equation, the regression equation of the communication time and the communication strength is calculated, and then the robust estimation such as the M estimation method is used. The regression equation may be recalculated. As the robust estimation, an L estimation method or an R estimation method may be used in addition to the M estimation method. In this way, if robust estimation is used, the influence on the regression equation of the wireless device that greatly deviates from the correlation between the communication time and the communication strength can be reduced, so that the wireless device that deviates from the correlation between the communication time and the communication strength can be reduced. Can be identified more accurately.

The present invention is not limited to the above-described embodiment, and can be realized with various configurations within a range not deviating from the gist thereof. For example, the technical features of the embodiments corresponding to the technical features in each of the embodiments described in the column of the outline of the invention may be used to solve some or all of the above-mentioned problems, or a part of the above-mentioned effects. Or, in order to achieve all of them, it is possible to replace or combine them as appropriate. Further, if the technical feature is not described as essential in the present specification, it can be appropriately deleted.

0, 20 ... Master unit 1-7, 21 ... Slave unit 10 ... Air conditioning control system 30 ... Wall A to H ... Point X, Y ... Building r1, r2, r3, r4 ... Correlation coefficient

Claims (2)

It is a grouping method that groups multiple wireless devices including a master unit of a wireless system placed in the building of a facility and a plurality of slave units.
(A) A step of executing communication between the plurality of wireless devices and acquiring communication time and communication strength in a combination of the two wireless devices, respectively.
(B) A step of identifying a wireless device that deviates from the correlation between the communication time and the communication strength, and
(C) A step of grouping the plurality of slave units together with the master unit except for the specified wireless device.
Equipped with
The step (b) is
(B1) A step of detecting a combination of the two wireless devices having the shortest communication time and selecting the two wireless devices as a group.
(B2) The shortest combination of the communication time between the wireless device included in the group and the wireless device not included in the group is detected, and the two wireless devices forming the combination are included in the group. The process of adding no wireless devices to the group and selecting a new group with one more wireless device,
(B3) A step of repeating the step (b2) and a step of repeating the step (b2).
(B4) Each time the group obtained in order in steps (b1) to (b3) is obtained, a step of calculating a correlation coefficient having two parameters of the communication time and the communication strength, and a step of calculating the correlation coefficient.
(B5) A step of identifying a wireless device that deviates from the correlation by using the correlation coefficient, and
Grouping methods , including . It is a grouping method that groups multiple wireless devices including a master unit of a wireless system placed in the building of a facility and a plurality of slave units.
(A) A step of executing communication between the plurality of wireless devices and acquiring communication time and communication strength in a combination of the two wireless devices, respectively.
(B) A step of identifying a wireless device that deviates from the correlation between the communication time and the communication strength, and
(C) A step of grouping the plurality of slave units together with the master unit except for the specified wireless device.
Equipped with
The step (b) is
(B1) A step of detecting a combination of the two wireless devices having the strongest communication strength and selecting the two wireless devices as a group.
(B2) The strongest combination of the communication strength between the wireless device included in the group and the wireless device not included in the group is detected, and the two wireless devices forming the combination are included in the group. The process of adding no wireless devices to the group and selecting a new group with one more wireless device,
(B3) A step of repeating the step (b2) and a step of repeating the step (b2).
(B4) Each time the group obtained in order in steps (b1) to (b3) is obtained, a step of calculating a correlation coefficient having two parameters of the communication time and the communication strength, and a step of calculating the correlation coefficient.
(B5) A step of identifying a wireless device that deviates from the correlation by using the correlation coefficient, and
Grouping methods, including.

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