JP6741992B2 - Control system - Google Patents

Description

The present invention relates generally to control systems, and more particularly to control systems capable of communicating with multiple terminals.

Conventionally, a remote monitoring control system (control system) for controlling a lighting load has been known, and is disclosed in Patent Document 1, for example. The control system described in Patent Document 1 is configured by connecting a plurality of terminals (terminals) to a transmission unit via a two-wire type signal line. The transmission unit always cyclically changes the address data included in the transmission signal, and constantly polls for sequentially accessing a plurality of terminals. At the time of constant polling, the control data included in the transmission signal is taken in by the terminal whose address data included in the transmission signal matches.

JP, 2003-109778, A

By the way, in the control system, it is desired to monitor individual states of a plurality of terminals. However, in the above-described conventional control system, when trying to monitor the individual states of a plurality of terminals, it is necessary to sequentially access the plurality of terminals, which may increase the time required for monitoring.

The present invention has been made in view of the above points, and an object of the present invention is to provide a control system capable of shortening the time required to monitor the individual states of a plurality of terminals.

A control system according to an aspect of the present invention includes a communication unit that communicates with a plurality of terminals, and a control unit that controls the communication unit. The control unit is configured to generate a request telegram for a request target group including two or more terminals among the plurality of terminals. The request message includes a command requesting a return of individual states of the two or more terminals. Further, the control unit is configured to cause the communication unit to transmit the request message to the plurality of terminals. The control unit is configured to receive a response signal from the two or more terminals as the request target group in a time division manner during a monitoring period after the transmission of the request message. The monitoring period is assigned to a first time slot assigned to the two or more terminals as the request target group among the plurality of terminals and a terminal other than the request target group among the plurality of terminals. A second time slot; The time slot for receiving the response signal is the first time slot. The receiving time slot when a specific event from a terminal other than the request target group occurs is the second time slot.
A control system according to an aspect of the present invention includes a communication unit that communicates with a plurality of terminals, and a control unit that controls the communication unit. The control unit is configured to generate a request telegram for a request target group including two or more terminals among the plurality of terminals. The request message includes a command requesting a return of individual states of the two or more terminals. Further, the control unit is configured to cause the communication unit to transmit the request message to the plurality of terminals. The control unit is configured to receive a response signal from the two or more terminals as the request target group in a time division manner during a monitoring period after the transmission of the request message. The monitoring period includes a contention access period used for communication between the plurality of terminals and the communication unit, separately from the time slot for receiving the response signal. In the competitive access section, the control unit receives one of the plurality of terminals when the communication unit receives a monitoring message that notifies the occurrence of a specific event from any one of the plurality of terminals. A control message including control contents of the controlled object group including the above terminals is configured to be transmitted from the communication unit to the one or more terminals as the controlled object group. The control message also serves as an affirmative response signal to the terminal that is the transmission source of the monitoring message.
A control system according to one aspect of the present invention includes a communication unit that communicates with a plurality of terminals, and a control unit that controls the communication unit. The control unit is configured to generate a request telegram for a request target group including two or more terminals among the plurality of terminals. The request message includes a command requesting a return of individual states of the two or more terminals. Further, the control unit is configured to cause the request message to be transmitted from the communication unit to the plurality of terminals. The control unit is configured to receive a response signal from the two or more terminals as the request target group in a time division manner during a monitoring period after the transmission of the request message. The monitoring period includes a contention access period used for communication between the plurality of terminals and the communication unit, separately from the time slot for receiving the response signal. In the contention access section, the control unit stops transmission of the request message and stops transmission of the response signal from the two or more terminals as the request target group when a predetermined condition is satisfied. Configured to let. The predetermined condition is that the communication unit receives a monitoring telegram for notifying the occurrence of a specific event from any one of the plurality of terminals, and the time required for processing the specific event is a predetermined time. Is to exceed.

The present invention can shorten the time required to monitor the individual states of a plurality of terminals.

FIG. 1 is a block diagram showing the configuration of a control system according to the first embodiment of the present invention. FIG. 2 is a block diagram showing the overall configuration of the above control system. FIG. 3 is a time chart showing the operation of the above control system. FIG. 4 is a time chart showing the operation of the control system of the comparative example. FIG. 5 is a time chart showing the operation of the modification of the control system according to the first embodiment of the present invention. FIG. 6 is a conceptual diagram showing an example of a format of a request message used in the control system according to the second embodiment of the present invention. FIG. 7 is a time chart showing the operation of the above control system. FIG. 8 is a time chart showing the operation of a modified example of the above control system. FIG. 9 is a time chart showing the operation of the control system according to the third embodiment of the present invention. FIG. 10 is a time chart showing an example of the operation in the contention access section in the control system of the above. FIG. 11 is a time chart showing the operation of the first modified example of the above control system. FIG. 12 is a time chart showing the operation of the second modified example of the above control system.

(Embodiment 1)
(1) Outline Hereinafter, the control system 10 of the present embodiment will be described with reference to FIGS. 1 and 2. The control system 10 of the present embodiment is a system used for facilities such as office buildings, stores, hospitals, schools, or factories, for controlling a control target such as a lighting fixture installed in the facility. In this embodiment, the case where the control system 10 is a lighting control system for controlling a lighting fixture will be described as an example.

The control system 10 includes a wireless unit 2 as shown in FIGS. The wireless unit 2 is configured to be able to communicate with the lighting controller 1. Further, the wireless unit 2 is configured to be capable of communicating with a plurality (N in the example of FIGS. 1 and 2) of terminals 31, 32,..., 3n (“n” is an integer). Hereinafter, each of the plurality of terminals 31, 32,..., 3n is referred to as a “terminal 3” unless the plurality of terminals 31, 32,. In the present embodiment, it is assumed that the plurality of terminals 3 are not included in the components of the control system 10.

The plurality of terminals 3 are mainly classified into two types, that is, a control terminal and a monitoring terminal. The terminal 3 as a control terminal is configured integrally with a lighting device that is a control target. Alternatively, the terminal 3 as the control terminal may be separate from the lighting fixture to be controlled. In this case, the terminal 3 as a control terminal is electrically connected to a lighting fixture or a relay provided on a power supply path to the lighting fixture. The terminal 3 as a control terminal has a function of controlling, for example, on/off of a lighting fixture, dimming, or toning according to a message transmitted from the wireless unit 2. The "telegram" here is a set of data transmitted or received between the devices, which is described according to a predetermined format.

The terminal 3 as a monitoring terminal is configured by, for example, a switch mounted on a wall or the like and receiving a user operation, or various sensors. The sensor here is, for example, a human sensor, an illuminance sensor, a heat ray sensor, a temperature sensor, or the like. The human sensor includes a sensor that has a function of not only detecting the presence or absence of a person but also measuring the number of persons existing within the detection range. The terminal 3 as a monitoring terminal transmits a message to the wireless unit 2 when a specific event occurs such as a switch detecting a user operation or a sensor detecting the presence of a person.

The wireless unit 2 has a function of relaying a signal between the lighting controller 1 and a plurality of terminals 3. For example, when a telegram is transmitted from the lighting controller 1 to the terminal 3, the wireless unit 2 receives the telegram from the lighting controller 1 and transmits the telegram to the terminal 3. In addition, when a message is transmitted from the terminal 3 to the lighting controller 1, the wireless unit 2 receives the message from the terminal 3 and transmits the message to the lighting controller 1.

A unique address is set for each terminal 3. The address of each terminal 3 is set using, for example, a dedicated address setter. The lighting controller 1 individually recognizes the terminal 3 using these addresses. In the present embodiment, description will be made assuming that one address is set for one terminal 3. However, not limited to this configuration, when one monitoring terminal is equipped with a plurality of switches or a plurality of sensors, a unique address may be set to each of the plurality of switches or the plurality of sensors. Similarly, when a plurality of lighting devices are connected to one control terminal, a unique address may be set for each of the plurality of lighting devices.

In the control system 10 of the present embodiment, the wireless unit 2 monitors the state of the terminal 3 by transmitting the request message M1 (see FIG. 3) to the plurality of terminals 3 regularly or irregularly. I do. The “request message M1” mentioned here includes a command for requesting a reply of the individual states of the two or more terminals 3 to a request target group including two or more terminals 3 among the plurality of terminals 3. It is a telegram. Further, the “state” mentioned here is, for example, the lighting state of the luminaire (ON/OFF of the luminaire, dimming ratio, color temperature, etc.) if the terminal 3 is a control terminal. The “state” is, for example, the state of various sensors when the terminal 3 is a monitoring terminal. Specifically, for example, when the terminal 3 is an illuminance sensor, the “state” is the illuminance in the detection range detected by the illuminance sensor. In addition, if the terminal 3 is, for example, a motion sensor, the “state” is the presence or absence of a person within the detection range detected by the motion sensor, and the number of people.

Then, the wireless unit 2 is configured to receive the response signal S1 from the two or more terminals 3 as the request target group in a time division method during the monitoring period T1 after the transmission of the request message M1. For this reason, in the control system 10 of the present embodiment, it is not necessary to sequentially transmit the request message M1 to the plurality of terminals 3 in the monitoring operation, that is, it is not necessary to sequentially access, so that the number of times of transmitting the request message M1 can be reduced. .. Therefore, in the control system 10 of the present embodiment, it is possible to reduce the time required to monitor the individual states of the plurality of terminals 3.

(2) Details The configuration of the control system 10 of this embodiment will be described in detail below with reference to FIGS. 1 and 2. As described above, the control system 10 of this embodiment includes the wireless unit 2 that can communicate with the lighting controller 1 as a component. Further, in the example of FIG. 2, the lighting controller 1 is configured to be able to communicate with the integrated controller 4.

The lighting controller 1 is wire-connected to the wireless unit 2 via a two-wire signal line 100. The illumination controller 1 is configured to be capable of bidirectionally transmitting and receiving telegrams by wire communication with the wireless unit 2. In the present embodiment, between the lighting controller 1 and the wireless unit 2, transmission and reception of a telegram are performed by a transmission signal composed of, for example, a bipolar (±24 V) time division multiplexed signal. Specifically, the lighting controller 1 outputs a transmission signal including a telegram to the signal line 100. As a result, the electronic message is transmitted from the lighting controller 1 to the wireless unit 2. In addition, the wireless unit 2 returns the message as a current mode signal during the return period of the transmission signal. As a result, a message is transmitted from the wireless unit 2 to the lighting controller 1. The “current mode signal” here is a signal represented by a change in current caused by switching between a state in which the line between the signal lines 100 is opened and a state in which a low impedance element is connected between the lines.

The wireless unit 2 is configured to be capable of bidirectionally transmitting and receiving electronic messages by wireless communication with a plurality of terminals 3. That is, the wireless unit 2 transmits and receives a telegram to and from the lighting controller 1 by wired communication, and transmits and receives a telegram to and from the terminal 3 by wireless communication. Thereby, the wireless unit 2 can relay (transfer) a telegram received from the lighting controller 1 by wire communication to the terminal 3 by wireless communication. In addition, the wireless unit 2 can relay (transfer) a message received from the terminal 3 by wireless communication to the lighting controller 1 by wire communication. In the present embodiment, the communication method between the wireless unit 2 and the terminal 3 is, for example, a low power wireless that does not require a license (specific low power wireless) or wireless communication such as Wi-Fi (registered trademark). .. For this kind of low power radio, specifications such as the frequency band to be used and the antenna power are specified in each country according to the application. In Japan, low-power radio that uses radio waves in the 920 MHz band or the 420 MHz band is specified.

The wireless unit 2 has a wired communication unit 21, a control unit 22, and a communication unit 23.

The wired communication unit 21 is a communication interface for performing communication with the lighting controller 1, and is connected to the lighting controller 1 via a signal line 100. The wire communication unit 21 bidirectionally transmits and receives a message with the lighting controller 1 by wire communication using a transmission signal.

The control unit 22 controls the wired communication unit 21 and the communication unit 23. The control unit 22 is composed of a microcomputer having CPU (Central Processing Unit) and memory as main components. In other words, the control unit 22 is realized by a computer having a CPU and a memory, and the computer functions as the control unit 22 when the CPU executes the program stored in the memory. Although the program is recorded in advance in the memory of the control unit 22 here, it is provided by being recorded through a telecommunication line such as the Internet or through a wireless signal from the wireless unit 2 or recorded in a recording medium such as a memory card. Good.

The communication unit 23 is a communication interface for communicating with a plurality of terminals 3 subordinate to the wireless unit 2. The communication unit 23 bidirectionally transmits and receives a message with the terminal 3 by wireless communication. The addresses of the plurality of terminals 3 that can communicate with the communication unit 23, that is, the plurality of terminals 3 under the wireless unit 2 are registered in advance in the memory of the control unit 22 or the like. In other words, the communication unit 23 can communicate only with the terminal 3 whose address is registered.

The wireless unit 2 configured as described above is arranged at a position suitable for wireless communication with a plurality of terminals 3, such as a ceiling of a room in which a plurality of terminals 3 are installed. .. However, the wireless unit 2 is not limited to the configuration that directly communicates with the plurality of terminals 3. For example, the wireless unit 2 may indirectly communicate with the terminal 3 located at a position where the wireless signal (radio wave) from the wireless unit 2 does not reach via a relay.

Further, a plurality of wireless units 2 can be connected to one lighting controller 1. That is, although only one wireless unit 2 is shown in FIGS. 1 and 2, a plurality of wireless units 2 may be connected to the signal line 100. In this case, two or more terminals 3 are provided under each of the plurality of wireless units 2.

Next, the configuration of the terminal 3 will be described with reference to FIG. However, since the basic configuration of the plurality of terminals 31, 32,..., 3n is common, only one terminal 31 among the plurality of terminals 31, 32,. However, the description of the configuration of the other terminals 32, 33,..., 3n is omitted.

The terminal 3 includes a terminal-side communication unit 301, a terminal-side control unit 302, and a functional module 303.

The terminal-side communication unit 301 is a communication interface for communicating with the control system 10 (wireless unit 2). The terminal-side communication unit 301 bidirectionally transmits and receives a message with the wireless unit 2 by wireless communication. The address of the wireless unit 2 with which the terminal-side communication unit 301 can communicate is registered in advance in the memory or the like of the terminal-side control unit 302. In other words, the terminal-side communication unit 301 can communicate only with the wireless unit 2 whose address is registered.

The terminal-side control unit 302 controls the terminal-side communication unit 301 and the functional module 303. The terminal-side control unit 302 is composed of a microcomputer whose main components are a CPU and a memory. In other words, the terminal-side control unit 302 is realized by a computer having a CPU and a memory, and the CPU functions as the terminal-side control unit 302 by executing the program stored in the memory. Although the program is recorded in advance in the memory of the terminal-side control unit 302 here, the program may be provided through an electric communication line such as the Internet or in a recording medium such as a memory card.

The function module 303 is a module that realizes a function other than communication with the control system 10 (wireless unit 2) in the terminal 3. In the case of the terminal 3 as the control terminal, the functional module 303 has a function of controlling on/off, dimming, color adjustment, or the like of the lighting device to be controlled. If the terminal 3 is a monitoring terminal, the functional module 303 has a function as a switch or various sensors. That is, the terminal 3 has a configuration in which the function of the function module 303 is added with the function of communicating with the control system 10.

Further, although not shown in FIGS. 1 and 2, a wired terminal is connected to the signal line 100. Unlike the terminal 3, the wired terminal is directly connected to the lighting controller 1 by the signal line 100 without using the wireless unit 2. The wired terminal basically has the same configuration as the terminal 3, and is classified into two types, that is, a control terminal and a monitoring terminal, like the terminal 3. However, the terminal-side communication unit of the terminal 3 is different from the terminal-side communication unit of the terminal 3 in that the terminal-side communication unit of the wired terminal transmits and receives bidirectional telegrams by wire communication with the lighting controller 1 without going through the wireless unit 2. Is different. In the present embodiment, transmission and reception of telegrams are performed between the lighting controller 1 and the wired terminal by transmission signals.

The integrated controller 4 is configured to communicate with the lighting controller 1 as well as the air conditioning controller 5, for example. The air conditioning controller 5 constitutes, apart from the control system 10, an air conditioning control system for controlling air conditioning equipment (air conditioner). The integrated controller 4 is a higher-level device of the lighting controller 1 and the air conditioning controller 5, and integrally manages the lighting control system and the air conditioning control system including the control system 10. That is, the integrated controller 4 can control both the lighting equipment and the air conditioning equipment provided in the facility.

(3) Operation Next, the operation of the control system 10 according to the present embodiment will be described. Hereinafter, a monitoring operation for monitoring the state of the terminal 3 and a control operation for controlling the terminal 3 by the control system 10 will be described in order.

(3.1) Monitoring Operation First, the monitoring operation will be described with reference to FIG. As an example below, it is assumed that the wireless unit 2 transmits the request message M1 to all of the plurality of terminals 31, 32,..., 3n. That is, hereinafter, all of the plurality of terminals 31, 32,..., 3n are included in the request target group. Further, in the following, the wireless unit 2 periodically transmits the request message M1. However, when the request message M1 is received from the lighting controller 1, for example, the request message M1 is received. You may send it.

The wireless unit 2 transmits the request message M1 to the plurality of terminals 31, 32,..., 3n by a broadcast method. Then, the wireless unit 2 waits for a response signal S1 from the plurality of terminals 31, 32,..., 3n after the transmission of the request message M1 until the monitoring period T1 elapses. Here, the monitoring period T1 is a fixed time (for example, several tens of seconds) starting from the transmission timing of the request message M1, and is divided into a plurality of time slots TS0. The plurality of time slots TS0 are assigned to the plurality of terminals 31, 32,..., 3n in a one-to-one manner in advance. That is, each of the plurality of terminals 31, 32,..., 3n stores the time slot TS0 assigned to itself during the monitoring period T1 in the memory or the like.

The terminals 31, 32,..., 3n that have received the request message M1 transmit the response signal S1 to the request message M1 to the wireless unit 2 using the time slots TS0 assigned to themselves. That is, the terminals 31, 32,..., 3n receive the request message M1 and transmit the response signal S1 to the communication unit 23 in a time division manner. The response signal S1 includes data indicating the state of the terminal 3. That is, for example, the response signal S1 transmitted by the terminal 31 includes data indicating the state of the terminal 31. In the example of FIG. 3, the terminal 31 transmits the response signal S1 to the wireless unit 2 in the first time slot TS0 of the monitoring period T1. Similarly, the terminal 32 transmits the response signal S1 to the wireless unit 2 in the second time slot TS0 of the monitoring period T1, and the terminal 3n transmits the response signal S1 to the wireless unit 2 in the nth time slot TS0 of the monitoring period T1.

The wireless unit 2 receives the response signal S1 from the terminal 31 in the first time slot TS0 of the monitoring period T1. Similarly, the wireless unit 2 receives the response signal S1 from the terminal 32 in the second time slot TS0 of the monitoring period T1, and the response signal S1 from the terminal 3n in the nth time slot TS0 of the monitoring period T1. To receive. That is, the wireless unit 2 receives the response signals S1 from all the plurality of terminals 3 as the request target group in the time division method in the monitoring period T1 after the transmission of the request message M1.

Upon receiving the response signal S1, the wireless unit 2 stores the data, which is included in the response signal S1 and represents the state of each terminal 3, in a memory or the like. Then, in response to a request from the lighting controller 1, the wireless unit 2 individually or collectively transmits data representing the states of all the plurality of terminals 3 as a request target group to the lighting controller 1.

(3.2) Control Operation Next, the control operation will be described. Here, it is assumed that a control message (control message M3; see FIG. 9) is generated in the lighting controller 1. The “control telegram M3” mentioned here includes the control content of the control target group including one or more terminals 3 among the plurality of terminals 3. For example, the lighting controller 1 receives a message for monitoring (monitoring message M2. FIG. 9) from a monitoring terminal under the control of a wireless unit different from the wireless unit 2 to which the control message M3 is transmitted or a monitoring terminal that is a wired terminal. When the control message M3 is received, the control message M3 is generated. The monitoring message M2 is transmitted from the monitoring terminal to the lighting controller 1 via the wireless unit 2 when a specific event occurs in the monitoring terminal.

The lighting controller 1 that has generated the control message M3 transmits the control message M3 via the wireless unit 2 to the control terminal corresponding to the address of the monitoring terminal that is the transmission source of the monitoring message M2. The control telegram M3 transmitted at this time includes at least a data area indicating the control content and an address area designating the destination of the control telegram. Here, the address area includes the address of the terminal 3 (control terminal) of the transmission destination (destination). Specifically, the lighting controller 1 first transmits a control message M3 to the wireless unit 2 using a transmission signal. The wireless unit 2 that has received the control message M3 from the lighting controller 1 transmits the control message M3 by wireless communication to the terminal 3 (control terminal) whose address is included in the control message M3. The terminal 3 (control terminal) that has received the control message M3 controls, for example, on/off, dimming, or toning of the lighting device to be controlled according to the control content of the data area.

Further, the control system 10 of the present embodiment can also perform collective control operation. The term "collective control" as used herein means that a controlled object group including two or more terminals 3 among a plurality of terminals (10 in the present embodiment) that are control terminals performs the same control. means.

In the collective control operation, the lighting controller 1 sends a control message via the wireless unit 2 to a controlled object group including two or more terminals 3 corresponding to the address of the monitoring terminal that is the transmission source of the monitoring message M2. Send M3. As a result, the plurality of terminals 3 (control terminals) that have received the control message M3 perform control according to the same control content of the data area.

(4) Effects First, in describing the effects of the control system 10 of the present embodiment, the operation of the control system according to the comparative example of the present embodiment (hereinafter, referred to as “control system of the comparative example”) will be described with reference to FIG. 4. explain. Hereinafter, in the control system of the comparative example, the same components as those of the control system 10 of the present embodiment will be described with common reference numerals.

In the control system of the comparative example, unlike the control system 10 of the present embodiment, the wireless unit 2 transmits the request message M1 to each of the plurality of terminals 3 in the monitoring operation, so that each of the plurality of terminals 3 is transmitted. From the response signal S1. For this reason, in the control system of the comparative example, the time required for the monitoring operation per terminal 3 is increased by the transmission time of the request message M1. If the number of terminals 3 is about several, the control system of the comparative example does not require much time for the monitoring operation. However, when the number of terminals 3 is large, for example, hundreds, in the control system of the comparative example, the transmission time of the request message M1 increases in proportion to the number of terminals 3, and as a result, the time required for the monitoring operation is increased. It can be long. That is, in the control system of the comparative example, since data is collected by one-to-one polling communication in order to monitor the state of the terminal 3, there is a problem that communication efficiency is poor and communication time tends to be long.

On the other hand, in the control system 10 of the present embodiment, in the monitoring operation, if the wireless unit 2 once transmits the request message M1, it is possible to receive the response signals S1 from the plurality of terminals 3 in a time division manner. .. That is, in the control system 10 of the present embodiment, since it is not necessary to transmit the request message M1 for each of the plurality of terminals 3, the transmission time of the request message M1 does not increase in proportion to the number of terminals 3. Therefore, in the control system 10 of the present embodiment, the number of packets transmitted or received by the wireless unit 2 in the monitoring operation is about half that in the control system of the comparative example, and the communication efficiency can be improved. As a result, in the control system 10 of the present embodiment, even when the number of terminals 3 is large, for example, hundreds, the time required for the monitoring operation, that is, the time required for monitoring the individual states of the plurality of terminals 3. Can be shortened.

(5) Modified Example Hereinafter, a modified example of the control system 10 of the present embodiment will be described. In the present embodiment, the monitoring period T1 is defined by a fixed time starting from the transmission timing of the request message M1. On the other hand, in this modification, the monitoring period T1 is defined based on the transmission timing of the synchronization signal S2 (beacon) as shown in FIG. The “synchronization signal S2” referred to here is a signal that the lighting controller 1 transmits to the plurality of terminals 3 via the wireless unit 2, and for example, the lighting controller 1, the wireless unit 2, and the plurality of terminals 3 are connected. Used to synchronize time on each.

Specifically, in this modification, the synchronization period T0, which is the transmission interval of the synchronization signal S2, is divided into a plurality of time slots TS0. Then, one of the plurality of time slots TS0 is assigned to the transmission of the request message M1 by the wireless unit 2, and the plurality of time slots TS0 after the transmission of the request message M1 is assigned to the monitoring period T1. As described above, the monitoring period T1 may be defined by the request telegram M1 different from the synchronization signal S2, or may be defined by the synchronization signal S2.

(6) Other Modifications Hereinafter, other modifications of the control system 10 of the present embodiment will be described. In the present embodiment, the plurality of terminals 31, 32,..., 3n are all included in the request target group, but the request target group only needs to include two or more terminals 3. In this case, among the terminals 3 that have received the request message M1, only the terminal 3 as the request target group may transmit the response signal S1, and the terminals 3 not included in the request target group may discard the request message M1.

Further, in the present embodiment, when two or more terminals 3 as a request target group among the plurality of terminals 3 all receive the request message M1, the response signal S1 is transmitted to the wireless unit 2 (communication unit 23). However, other configurations may be used. For example, one or more terminals 3 of the plurality of terminals 3 transmit the response signal S1 when receiving the request message M1, but the other terminals 3 do not transmit the response signal S1 even when receiving the request message M1. It may be configured as follows.

Further, in the present embodiment, the wireless unit 2 sets the transmission target of the control message M3 to the control terminal, but the transmission target of the control message M3 may be the monitoring terminal. In this case, the wireless unit 2 can perform control such as switching the operation of the monitoring terminal on/off.

That is, in this embodiment, the monitoring terminal may have a function as a control terminal. Similarly, the control terminal may have a function as a monitoring terminal. As described above, the plurality of terminals 3 need not be clearly classified into two types, that is, the control terminal and the monitoring terminal, and may include a terminal having both a control terminal and a monitoring terminal.

Further, in the present embodiment, the wireless unit 2 receives the data from the terminal 3 as a monitoring terminal in a time division manner in the monitoring period T1 after the transmission of the request message M1, but the data from the terminal 3 is received. The reception timing is not limited to this. For example, the wireless unit 2 may receive data from the terminal 3 as a monitoring terminal in a contention access period T2 described later. In other words, the monitoring terminal may not only transmit the data (response signal S1) in the time division method in the monitoring period T1, but may also transmit the data in the contention access period T2.

Further, in the present embodiment, an example has been shown in which the communication between the lighting controller 1 and the wireless unit 2 is wired communication, and the communication between the wireless unit 2 and the plurality of terminals 3 is wireless communication. Not limited to For example, the communication between the lighting controller 1 and the wireless unit 2 may be wireless communication, or the communication between the wireless unit 2 and the plurality of terminals 3 may be wired communication.

Further, it is not essential that the lighting controller 1 be involved in the processing until a specific event occurs in the terminal 3 (monitoring terminal) and the terminal 3 (control terminal) corresponding to this monitoring terminal is controlled. For example, when the monitoring terminal in which a specific event has occurred and the control terminal corresponding to this monitoring terminal are under the same wireless unit 2, the lighting controller 1 is not involved and the monitoring message M2 is received. The wireless unit 2 may directly transmit the control message M3. That is, the wireless unit 2 that receives the monitoring message M2 sends the control message M3 to the control terminal corresponding to the address of the terminal 3 (monitoring terminal) included in the monitoring message M2 without passing through the lighting controller 1. You may send it. In this case, the control message M3 is generated by the wireless unit 2.

In addition, in the present embodiment, it has been described that the plurality of terminals 3 are not included in the components of the control system 10, but the present invention is not limited to this, and the plurality of terminals 3 are included in the components of the control system 10. May be.

Further, in the present embodiment, the case where the lighting controller 1 is configured to be communicable with the integrated controller 4 has been described as an example, but the integrated controller 4 is not an essential configuration and can be appropriately omitted.

Further, in the present embodiment, the case where the control system 10 is an illumination control system has been exemplified, but the present invention is not limited to this example, and the control system 10 can be applied to control of various control targets. For example, the control system 10 may be an air conditioning control system for controlling an air conditioner (air conditioner) or a system for controlling a plurality of types of control targets (for example, lighting equipment and air conditioner). May be. Further, the control system 10 is not limited to a non-residential facility such as an office building, but may be used for a house such as a detached house or an apartment house.

(Embodiment 2)
(1) Details Hereinafter, the control system 10 according to the second embodiment will be described with reference to FIGS. 6 and 7. However, since the basic configuration of the control system 10 of the present embodiment is common to that of the control system 10 (including the modified example) of the first embodiment, common parts are designated by the same reference numerals and description thereof will be omitted. .. In the first embodiment, the wireless unit 2 transmits the request message M1 to all of the plurality of terminals 3 by the broadcast method. On the other hand, in the present embodiment, as shown in FIGS. 6 and 7, the wireless unit 2 requests the request target group including two or more terminals 3 out of the plurality of terminals 3 by a multicast method to request message M1. Are being sent.

In the present embodiment, the wireless unit 2 changes the format of the request message M1 transmitted to the terminal 3 to a format including the address area F1 as shown in FIG. Here, the address area F1 is an area for designating a destination of the request message M1, and a plurality of unit information B1, B2,..., One-to-one corresponding to a plurality of terminals 3 subordinate to the wireless unit 2. It is composed of a set of Bn. Each of the plurality of unit information B1, B2,..., Bn is a value having a predetermined number of bits, and is information indicating whether or not each of the plurality of terminals 3 is included in the request target group.

In the example of FIG. 6, each of the plurality of unit information B1, B2,..., Bn consists of 1 bit (1/0) bit, and is “1” when included in the request target group, and included in the request target group. If not, it is represented by "0". The address area F1 is configured by arranging such 1-bit unit information as many as the number of terminals 3 subordinate to the wireless unit 2. That is, in this embodiment, the address area F1 is composed of a bit string of n bits. The plurality of unit information B1, B2,..., Bn correspond one-to-one to the plurality of terminals 31, 32,. That is, the unit information B1 corresponds to the terminal 31, the unit information B2 corresponds to the terminal 32, and the unit information Bn corresponds to the terminal 3n. Therefore, in the example of FIG. 6, for example, the terminals 31, 32, 34, 35, 39 corresponding to the unit information B1, B2, B4, B5, B9 are included in the request target group. Further, for example, the terminals 33, 36, 37, 38 corresponding to the unit information B3, B6, B7, B8 are not included in the request target group.

The terminal 3 that has received the request message M1 analyzes the unit information B1, B2,..., Bn included in the address area F1 and determines whether or not it is included in the request target group. That is, whether the terminal 3 is included in the request target group based on the values of the unit information B1, B2,..., Bn corresponding to itself among the unit information B1, B2,..., Bn included in the address area F1. Determine whether or not. , Bn necessary for identifying the unit information B1, B2,..., Bn corresponding to itself in the terminal 3, the correspondence between the unit information B1, B2,. Remembered in.

In the present embodiment, the terminal 3 outputs the response signal S1 if the value of the unit information B1, B2,..., Bn corresponding to itself among the plurality of unit information B1, B2,. It transmits to the wireless unit 2. On the other hand, the terminal 3 discards the request message M1 if the value of the unit information B1, B2,..., Bn corresponding to itself among the plurality of unit information B1, B2,..., Bn is “0”. In the example of FIG. 6, the five terminals 31, 32, 34, 35, 39 as the request target group transmit the response signal S1 to the wireless unit 2 (see FIG. 7).

That is, the monitoring period T1 includes a first time slot TS1 and a second time slot TS2, as shown in FIG. The first time slot TS1 is assigned to two or more terminals 3 as a request target group among the plurality of terminals 3. Here, the time slot TS0 of each of the terminals 31, 32, 34, 35, 39 is the first time slot TS1. The second time slot TS2 is assigned to the terminals 3 other than the request target group among the plurality of terminals 3. Here, the time slot TS0 of each of the terminals 33, 36, 37, 38 is the second time slot TS2. Then, the terminal 3 included in the request target group transmits the response signal S1 to the wireless unit 2 in the first time slot TS1 assigned to itself. In other words, for the wireless unit 2, the time slot TS0 for receiving the response signal S1 is the first time slot TS1.

In the present embodiment, it is possible to change the terminal 3 designated as the request target group for each monitoring period T1. Therefore, in the present embodiment, the wireless unit 2 can change the period for acquiring the data representing the state for each terminal 3, and can efficiently collect the data. For example, assume that the monitoring period T1 is repeated in a 1-minute cycle. In this case, the wireless unit 2 designates, for example, the terminal 3 as a control terminal configured integrally with the lighting fixture as a request target group every 10 monitoring periods T1, and thus data indicating the state in a 10-minute cycle. It is possible to obtain Further, the wireless unit 2 can acquire the data indicating the state in a one-minute cycle by designating the terminal 3 as a monitoring terminal such as a temperature sensor as a request target group for each monitoring period T1. It is possible.

Here, in the present embodiment, it is assumed that the encoding method of the unit information B1, B2,..., Bn is an NRZ (Non Return to Zero) method, for example. The NRZ method is a single-current method in which 1 bit (“0” or “1”) is represented by the presence/absence of a voltage, and the potential is not returned to “0” for each bit. In this case, the unit information B1, B2,..., Bn consists of 1-bit data as described above. However, the encoding method of the unit information B1, B2,..., Bn is not limited to this method, and may be, for example, an RZ (Return to Zero) method, an AMI code (Alternate Mark Inversion code) method, or the like. Further, the encoding method of the unit information B1, B2,..., Bn is 2 bits for 1 bit (“0” or “1”) such as Manchester encoding method or CMI code (Code Mark Inversion code) method. A method in which the bit code is converted and represented may be used. That is, in the Manchester encoding system, “0” is represented by 2 bits of “01” and “1” is represented by 2 bits of “10”, and thus each of the unit information B1, B2,..., Bn. Consists of a 2-bit bit string.

(2) Modified Example Hereinafter, a modified example of the control system 10 of the present embodiment will be described. In the present embodiment, the second time slot TS2 is an empty slot that neither the wireless unit 2 nor the plurality of terminals 3 use for communication. On the other hand, in the present modified example, when the terminal 3 included in the request target group has an empty slot (second time slot TS2) before the time slot TS0 assigned to itself, the response signal S1 is sent in the empty slot. To send. Specifically, the terminal 3 included in the request target group analyzes the unit information B1, B2,..., Bn included in the address area F1 and determines the order in which the terminal 3 transmits the response signal S1. For example, the terminal 34 is assigned the fourth time slot TS0 in the monitoring period T1, but in the example of FIG. 6, the response signal S1 is transmitted in the third order. Therefore, as shown in FIG. 8, the terminal 34 transmits the response signal S1 in the third time slot TS0 (empty slot) in the monitoring period T1.

As described above, the terminal 3 included in the request target group transmits the response signal S1 in the second time slot TS2 (empty slot), and as a result, the monitoring period T1 includes only the first time slot TS1. Will be done. That is, the time slot TS0 included in the monitoring period T1 is the time slot TS0 for receiving the response signal S1 and is allocated only to one or more terminals 3 as a request target group among the plurality of terminals 3. Will be there. In this case, in comparison with the case where the time slot TS0 for receiving the response signal S1 is also assigned to the terminal 3 not included in the request target group, it is possible to monitor the individual states of the two or more terminals 3 as the request target group. It is possible to further reduce the time required.

(Embodiment 3)
(1) Details Hereinafter, the control system 10 according to the third embodiment will be described with reference to FIG. 9. However, since the basic configuration of the control system 10 of the present embodiment is common to that of the control system 10 (including the modified example) of the first embodiment, common parts are designated by the same reference numerals and description thereof will be omitted. .. In the control system 10 of the present embodiment, as shown in FIG. 9, the monitoring period T1 includes a contention access period T2 in addition to the time slot TS0 for receiving the response signal S1. The “competitive access section T2” here is a period used for communication between the plurality of terminals 3 and the wireless unit 2 (communication unit 23). In other words, in the competitive access section T2, both the plurality of terminals 3 and the wireless unit 2 can be used.

In the present embodiment, the contention access period T2 is composed of two time slots TS0 provided between the time slot TS0 of the terminal 33 and the time slot TS0 of the terminal 34. These time slots TS0 that form the contention access section T2 are provided separately from the plurality of time slots TS0 assigned to the plurality of terminals 3.

In the competitive access section T2, for example, the terminal 3 as the monitoring terminal can transmit the monitoring message M2 to the wireless unit 2 when a specific event occurs. In the example of FIG. 9, the terminal 32 as the monitoring terminal transmits the monitoring message M2 to the wireless unit 2. In the competitive access section T2, for example, the wireless unit 2 relays the control message M3 generated by the lighting controller 1 to the control terminal corresponding to the address of the monitoring terminal that is the transmission source of the monitoring message M2.

That is, in the present embodiment, the wireless unit 2 (control unit 22) receives the monitoring telegram M2 from any one of the plurality of terminals 3 by the wireless unit 2 (communication unit 23) in the competitive access section T2. Then, it is configured to execute the following operations. That is, the wireless unit 2 (control unit 22) causes the control message M3 to be transmitted from the wireless unit 2 (communication unit 23) to one or more terminals 3 as a controlled object group. In the example of FIG. 9, the wireless unit 2 transmits the control message M3 to the terminal 33 as the control terminal that is the control target.

As described above, the control system 10 of the present embodiment can execute the control operation even during the monitoring period T1 during which the monitoring operation is being executed. Specifically, during execution of the monitoring operation, even if any of the switches (monitoring terminal) is operated by the user, it is possible to turn on/off the lighting fixture (control terminal) corresponding to the switch. Therefore, in the control system 10 of the present embodiment, the time from the occurrence of a specific event until the control of the terminal 3 as the control terminal is executed is unlikely to be long, and immediate responsiveness is easily ensured.

By the way, the wireless unit 2 may transmit an affirmative response (ACK: ACKnowledgement) signal S3 to the monitoring message M2 to the monitoring terminal which is the transmission source of the monitoring message M2, as shown in FIG. 10, for example. In the example of FIG. 10, the terminal 3m (“m” is an integer) as the monitoring terminal transmits the monitoring message M2 to the wireless unit 2. Further, in the example of FIG. 10, the wireless unit 2 transmits the control message M3 to the terminal 3p (“p” is an integer) as the control terminal corresponding to the address of the terminal 3m that is the transmission source of the monitoring message M2. doing. Then, the wireless unit 2 transmits an affirmative response signal S3 to the monitoring message M2 to the terminal 3m before transmitting the control message M3. With this configuration, the monitoring terminal that is the transmission source of the monitoring message M2 can confirm that the wireless unit 2 has received the monitoring message M2.

On the other hand, in the present embodiment, the control message M3 also serves as the affirmative response signal S3 to the terminal 3 that is the transmission source of the monitoring message M2. Specifically, the terminal 3 which is the transmission source of the monitoring message M2 intercepts the control message M3 transmitted to the other terminal 3 (control terminal), so that the reception of the control message M3 is affirmative to the monitoring message M2. It is assumed that the response signal S3 has been transmitted. With this configuration, the time during which the wireless unit 2 occupies the contention access section T2 is shortened, and the contention access section T2 can be used efficiently. In addition, the wireless unit 2 may transmit the control message M3 not only to the terminal 3 (control terminal) to be controlled, but also to the terminal 3 (monitoring terminal) that is the transmission source of the monitoring message M2. In this case, the terminal 3 that is the transmission source of the monitoring message M2 can receive the control message M3 without intercepting.

(2) First Modification Hereinafter, a first modification of the control system 10 of the present embodiment will be described with reference to FIG. 11. In this modification, the contention access section T2 is not provided separately from the plurality of time slots TSO assigned to the plurality of terminals 3, but is assigned to an empty slot. That is, in this modification, the contention access period T2 is the second time slot TS2. In the example of FIG. 11, since the terminals 33, 36, 37, 38 are not included in the request target group, these time slots TS0 are empty slots (second time slot TS2). Therefore, in the example of FIG. 11, the time slot TS0 of the terminals 36, 37, 38 is the contention access section T2. In this modification, since it is not necessary to provide the contention access section T2 separately from the plurality of time slots TS0 assigned to the plurality of terminals 3 in the monitoring period T1, it is possible to further shorten the monitoring period T1. ..

Here, in the competitive access section T2, a time slot TS0 for the terminal 3 to send the monitoring message M2 to the wireless unit 2 and a time slot TS0 for the wireless unit 2 to send the control message M3 to the terminal 3 to be controlled. And are preferably ensured. Therefore, as in the present modification, it is preferable that the contention access period T2 is composed of two or more consecutive time slots TS0.

(3) Second Modification Hereinafter, a second modification of the control system 10 of the present embodiment will be described with reference to FIG. In this modification, the wireless unit 2 receives the monitoring message M2 and confirms the content of the monitoring message M2. When the wireless unit 2 determines that the time required for processing the monitoring message M2 exceeds the predetermined time, it stops the monitoring operation, that is, stops transmitting the request message M1. That is, in this modification, the wireless unit 2 (control unit 22) stops the transmission of the request message M1 when a predetermined condition is satisfied, and the response signals from the two or more terminals 3 as the request target group. It is configured to stop the transmission of S1. The predetermined condition is that the communication unit 23 receives the monitoring telegram M2 for notifying the occurrence of a specific event from any one of the plurality of terminals 3 and the time required for processing the specific event is a predetermined time. Is to exceed.

For example, it is assumed that the processing for a specific event, that is, the control content for the monitoring telegram M2 is to individually control the dimming ratio of the plurality of lighting fixtures (terminals 3). In this case, the control content cannot be executed only in the contention access section T2 included in one monitoring period T1, and the control must be performed over the plurality of contention access sections T2 assigned to the plurality of monitoring periods T1. Therefore, in this case, as a result, the time required for control becomes long, and it is difficult to secure the required immediate responsiveness.

On the other hand, in the present modified example, by stopping the monitoring operation, it is possible to secure the gathered time required to execute the above control content. In the example of FIG. 12, when the wireless unit 2 receives the monitoring message M2, it stops transmitting the request message M1 after receiving the monitoring message M2. Further, the wireless unit 2 transmits the stop message M4 to the plurality of terminals 3 in the time slot TS0 next to the time slot TS0 at which the monitoring message M2 is received. The “stop message M4” here includes a command to stop the transmission of the response signal S1 to the request message M1. Each of the plurality of terminals 3 that has received the stop message M4 stops the transmission of the response signal S1 after receiving the stop message M4 even when the terminal 3 itself is included in the request target group.

Then, in the stop period T3 after the stop of the monitoring operation, the wireless unit 2 transmits the control telegram M3 to each of the terminals 32, 33, 34, so that the dimming ratio of each of the terminals 32, 33, 34 is changed. It is controlled individually. “S4” in FIG. 12 is an affirmative response signal to the monitoring message M2. Therefore, in the present modification, the time required for control can be shortened and the required immediate responsiveness can be easily secured, as compared with the case where the control content for the monitoring message M2 is executed while executing the monitoring operation. ..

Here, the stopped monitoring operation may be restarted by, for example, the next transmission of the request message M1 as a trigger. For example, it is assumed that the monitoring operation is stopped in the contention access period T2 between the time slot TS0 of the terminal 33 and the time slot TS0 of the terminal 34. In this case, the stopped monitoring operation is restarted from the time when the terminal 34 transmits the response signal S1, triggered by the transmission of the request message M1 after the stop.

In addition, when the monitoring operation is stopped, the monitoring period T1 may be reset, for example, triggered by the next transmission of the request message M1. For example, it is assumed that the monitoring operation is stopped in the contention access period T2 between the time slot TS0 of the terminal 33 and the time slot TS0 of the terminal 34. In this case, the monitoring period T1 starts from the transmission of the response signal S1 by the terminal 31, triggered by the transmission of the request message M1 after the stop.

By the way, when the terminal 3 as the monitoring terminal generates a specific event, the operation at the time of transmitting the monitoring message M2 to the wireless unit 2 (communication unit 23) at least in the competitive access section T2 is the content of the specific event. May be different depending on.

That is, the terminal 3 as the monitoring terminal changes the transmission operation of the monitoring telegram M2 so that the occupancy rate of the competitive access section T2 becomes low in a predetermined case. The predetermined case is a case in which an event (hereinafter, also referred to as “low priority event”) in which required immediate responsiveness or requested reliability is lower than other events occurs. Examples of low priority events include a decrease or increase in the detected illuminance by the illuminance sensor and a decrease or increase in the detected temperature by the temperature sensor. The following four specific examples of how the terminal 3 as the monitoring terminal changes the transmission operation of the monitoring message M2 in the competitive access section T2 when such a low priority event occurs. ..

As a first specific example, the terminal 3 as a monitoring terminal monitors in accordance with the content of a specific event at least in the contention access section T2 so that the standby time becomes longer as the priority of the event becomes lower. The waiting time until the message M2 is transmitted is changed. In other words, when an event with a low priority occurs, the standby time becomes longer than when another event occurs, so that the occupancy rate of the competitive access section T2 due to the transmission of the monitoring message M2 becomes low. For example, when the CSMA/CA (Carrier Sense Multiple Access/Collision Avoidance) method is adopted, the back-off time corresponds to the waiting time.

As a second specific example, the terminal 3 as a monitoring terminal monitors in accordance with the content of a specific event at least in the contention access period T2 so that the number of retries decreases as the event priority decreases. The number of carrier sense retries before transmission of the message M2 is changed. That is, for example, in the CSMA/CA method, when an event with a low priority occurs, the number of retries of carrier sense before the transmission of the monitoring message M2 decreases, so that the competition access section T2 is occupied by the transmission of the monitoring message M2. The rate is low.

As a third specific example, the terminal 3 as a monitoring terminal monitors in accordance with the content of a specific event at least in the contention access period T2 so that the number of retransmissions decreases as the event priority decreases. The number of retransmissions of the message M2 is changed. That is, for example, the terminal 3 serving as the monitoring terminal retransmits the monitoring message M2 when the acknowledgment message is not returned to the monitoring message M2. When an event with a low priority occurs, the upper limit of the number of times the monitoring message M2 is retransmitted decreases, so that the occupancy rate of the competitive access section T2 due to the transmission of the monitoring message M2 decreases.

As a fourth specific example, the terminal 3 serving as a monitoring terminal monitors in accordance with the content of a specific event at least in the contention access period T2 so that the transmission power decreases as the event priority decreases. The transmission power of the message M2 is changed. That is, when an event with a low priority occurs, the transmission power of the monitoring message M2 decreases, and the occupancy rate of the competitive access section T2 due to the transmission of the monitoring message M2 decreases.

As described above, the control system 10 of the first aspect includes the communication unit 23 that communicates with the plurality of terminals 3 and the control unit 22 that controls the communication unit 23. The control unit 22 is configured to generate a request message M1 for a request target group including two or more terminals 3 among the plurality of terminals 3. The request message M1 includes a command for requesting the return of individual states of two or more terminals 3. Further, the control unit 22 is configured to transmit the request message M1 from the communication unit 23 to the plurality of terminals 3. The control unit 22 is configured to receive the response signals S1 from the two or more terminals 3 as the request target group in a time division manner during the monitoring period T1 after the transmission of the request message M1.

According to this configuration, it is not necessary to transmit the request message M1 for each of the plurality of terminals 3, so that the time required for the monitoring operation, that is, the time required for monitoring the individual states of the plurality of terminals 3 is shortened. Is possible.

Moreover, the control system 10 of the second aspect includes a plurality of terminals 3 in the first aspect. When two or more terminals 3 as a request target group among the plurality of terminals 3 all receive the request message M1, they are configured to transmit the response signal S1 to the communication unit 23 in a time division manner.

With this configuration, it is possible to more reliably monitor the individual states of the plurality of terminals 3 as the request target group. However, this configuration is not indispensable to the control system 10, and is configured such that at least one terminal 3 among the two or more terminals 3 as the request target group transmits the response signal S1 to the communication unit 23. It should have been done.

In addition, in the control system 10 of the third aspect, in the first or second aspect, the monitoring period T1 includes a first time slot TS1 and a second time slot TS2. The first time slot TS1 is assigned to two or more terminals 3 as a request target group among the plurality of terminals 3. The second time slot TS2 is assigned to a terminal 3 other than the request target group among the plurality of terminals 3. The time slot TS0 for receiving the response signal S1 is the first time slot TS1.

With this configuration, it is possible to change the terminal 3 designated as the request target group for each monitoring period T1. Therefore, in this configuration, it is possible to change the period for acquiring the data representing the state for each terminal 3, and it is possible to efficiently collect the data. However, this configuration is not an indispensable configuration for the control system 10, and the monitoring period T1 may be configured by only the first time slot TS1 with all of the plurality of terminals 3 as a request target group.

Further, in the control system 10 of the fourth aspect, in the first or second aspect, the time slot TS0 included in the monitoring period T1 is the time slot TS0 for receiving the response signal S1. The time slot TS0 is assigned only to one or more terminals 3 as a request target group among the plurality of terminals 3.

According to this configuration, as compared with the case where the time slot TS0 for receiving the response signal S1 is also assigned to the terminal 3 not included in the request target group, the individual states of the two or more terminals 3 as the request target group are It is possible to further reduce the time required for monitoring. However, this configuration is not an essential configuration for the control system 10, and the time slot TS0 for receiving the response signal S1 may be assigned to the terminal 3 not included in the request target group.

Further, in the control system 10 of the fifth aspect, in any one of the first to fourth aspects, the monitoring period T1 communicates with a plurality of terminals 3 separately from the time slot TS0 for receiving the response signal S1. It includes a contention access period T2 used for communication with the unit 23.

With this configuration, the control operation can be executed even during the monitoring period T1 during which the monitoring operation is being executed. For this reason, in this configuration, the time from the occurrence of a specific event until the control of the terminal 3 as the control terminal is executed is unlikely to be long, and immediate responsiveness is easily secured. However, this configuration is not essential for the control system 10, and the monitoring period T1 may not include the contention access section T2.

Further, in the control system 10 of the sixth aspect, in the third aspect, the monitoring period T1 includes a contention access section T2 used for communication between the plurality of terminals 3 and the communication unit 23. The contention access section T2 is the second time slot TS2.

According to this configuration, since it is not necessary to provide the conflicting access section T2 separately from the plurality of time slots TS0 assigned to the plurality of terminals 3 in the monitoring period T1, it is possible to further shorten the monitoring period T1. .. However, this configuration is not an indispensable configuration for the control system 10, and the contention access section T2 may be provided separately from the plurality of time slots TS0 in the monitoring period T1.

Further, in the control system 10 of the seventh aspect, in the fifth or sixth aspect, the control unit 22 is configured as follows. That is, in the competitive access section T2, the control unit 22 performs the following operation when the communication unit 23 receives the monitoring telegram M2 notifying the occurrence of a specific event from any one of the plurality of terminals 3. Is configured. The control unit 22 transmits, from the communication unit 23, the control telegram M3 including the control content of the control target group including one or more terminals 3 among the plurality of terminals 3 to the one or more terminals 3 as the control target group. Is configured to let. The control message M3 also serves as an affirmative response signal S3 to the terminal 3 which is the transmission source of the monitoring message M2.

With this configuration, the time during which the wireless unit 2 (control unit 22) occupies the contention access section T2 is shortened, and the contention access section T2 can be used efficiently. However, this configuration is not an essential configuration of the control system 10, and the wireless unit 2 (control unit 22) transmits an affirmative response signal S3 to the terminal 3 that is the transmission source of the monitoring message M2, separately from the control message M3. Good.

Further, in the control system 10 of the eighth aspect, in any one of the fifth to seventh aspects, the control unit 22 is configured as follows. That is, in the competitive access section T2, the control unit 22 stops the transmission of the request message M1 and transmits the response signal S1 from the two or more terminals 3 as the request target group when the predetermined condition is satisfied. It is configured to stop. The predetermined condition is that the communication unit 23 receives the monitoring telegram M2 for notifying the occurrence of a specific event from any one of the plurality of terminals 3 and the time required for processing the specific event is a predetermined time. Is to exceed.

According to this configuration, the time required for control can be shortened and the required immediate responsiveness can be easily secured, as compared with the case where the control content for the monitoring telegram M2 is executed while executing the monitoring operation. However, this configuration is not an essential configuration for the control system 10, and the wireless unit 2 (control unit 22) does not have to stop the transmission of the request message M1 and two or more terminals 3 as a request target group. It is not necessary to stop the transmission of the response signal S1 from.

Moreover, the control system 10 of the ninth aspect includes the one or more monitoring terminals included in the plurality of terminals 3 in any one of the fifth to eighth aspects. One or more monitoring terminals are configured to transmit a monitoring message M2 to the communication unit 23, which notifies the occurrence of a specific event when a specific event occurs. At least one monitoring terminal changes the waiting time until the monitoring message M2 is transmitted, depending on the content of the specific event, at least in the competitive access section T2.

According to this configuration, for example, when an event with a low priority occurs, the waiting time is made longer than when another event occurs, so that the occupancy rate of the competitive access section T2 due to the transmission of the monitoring message M2 can be reduced. However, this configuration is not essential for the control system 10, and the waiting time until the monitoring terminal transmits the monitoring message M2 may be constant regardless of the content of the specific event.

Moreover, the control system 10 of the tenth aspect includes one or more monitoring terminals included in the plurality of terminals 3 in any one of the fifth to eighth aspects. One or more monitoring terminals are configured to transmit a monitoring message M2 to the communication unit 23, which notifies the occurrence of a specific event when a specific event occurs. At least one of the monitoring terminals changes the number of times of carrier sense retries before transmission of the monitoring message M2 in accordance with the content of a specific event at least in the competitive access section T2.

According to this configuration, for example, when an event of low priority occurs, the number of retries of carrier sense is reduced as compared with the time of occurrence of another event, so that the occupancy rate of the competitive access section T2 due to the transmission of the monitoring message M2 is reduced. It can be reduced. However, this configuration is not an essential configuration for the control system 10, and the number of times of carrier sense retries before transmission of the monitoring message M2 in the monitoring terminal may be constant regardless of the content of the specific event.

Further, the control system 10 of the eleventh aspect includes the one or more monitoring terminals included in the plurality of terminals 3 in any of the fifth to eighth aspects. One or more monitoring terminals are configured to transmit a monitoring message M2 to the communication unit 23, which notifies the occurrence of a specific event when a specific event occurs. One or more monitoring terminals change the number of retransmissions of the monitoring message M2 according to the content of a specific event at least in the competitive access section T2.

According to this configuration, for example, when an event with a low priority occurs, the number of times the monitoring message M2 is retransmitted is reduced compared to when another event occurs, so that the occupancy rate of the competitive access section T2 due to the transmission of the monitoring message M2 is reduced. Can be reduced. However, this configuration is not an indispensable configuration for the control system 10, and the number of times the monitoring message M2 is retransmitted in the monitoring terminal may be constant regardless of the content of a specific event.

In addition, the control system 10 of the twelfth aspect includes the one or more monitoring terminals included in the plurality of terminals 3 in any one of the fifth to eighth aspects. One or more monitoring terminals are configured to transmit a monitoring message M2 to the communication unit 23, which notifies the occurrence of a specific event when a specific event occurs. At least one monitoring terminal changes the transmission power of the monitoring telegram M2 according to the content of a specific event at least in the competitive access section T2.

According to this configuration, for example, when an event with a low priority occurs, the transmission power of the monitoring message M2 is made smaller than that at the time of the occurrence of another event, thereby occupying the contention access section T2 due to the transmission of the monitoring message M2. Can be reduced. However, this configuration is not an essential configuration for the control system 10, and the transmission power of the monitoring message M2 in the monitoring terminal may be constant regardless of the content of the specific event.

The control system 10 according to the first to third embodiments has been described above. However, Embodiments 1 to 3 described above are merely one of various embodiments of the present invention, and the above Embodiments 1 to 3 are various according to the design etc. as long as the object of the present invention can be achieved. Can be changed.

10 control system 22 control unit 23 communication unit 3, 31, 32,..., 3n terminal M1 request message M2 monitoring message M3 control message S1 response signal S3 affirmative response signal T1 monitoring period T2 competitive access period TS0 time slot TS1 first time slot TS2 second time slot

Claims (10)

A communication unit that communicates with multiple terminals,
A control unit for controlling the communication unit,
The control unit generates a request message including a command for requesting a reply of each state with respect to a request target group including two or more terminals of the plurality of terminals, and the request message is the communication unit. Is configured to be transmitted to the plurality of terminals from
The control unit is configured to receive a response signal from the two or more terminals as the request target group in a time division system during a monitoring period after the transmission of the request message ,
The monitoring period is
A first time slot assigned to the two or more terminals as the request target group among the plurality of terminals;
A second time slot assigned to a terminal other than the request target group among the plurality of terminals,
The time slot for receiving the response signal is the first time slot,
A control system , wherein a reception time slot when a specific event occurs from a terminal other than the request target group is the second time slot . The control system includes the plurality of terminals,
The two or more terminals as the request target group among the plurality of terminals are configured to transmit the response signal to the communication unit in a time division manner when receiving the request message. The control system according to claim 1, wherein: The monitoring period includes a contention access section used for communication between the plurality of terminals and the communication unit,
The control system according to claim 1, wherein the contention access section is the second time slot. A communication unit that communicates with multiple terminals,
A control unit for controlling the communication unit,
The control unit generates a request message including a command for requesting a reply of each state with respect to a request target group including two or more terminals of the plurality of terminals, and the request message is the communication unit. Is configured to be transmitted to the plurality of terminals from
The control unit is configured to receive a response signal from the two or more terminals as the request target group in a time division system during a monitoring period after the transmission of the request message,
The monitoring period includes, in addition to the time slot for receiving the response signal, a contention access period used for communication between the plurality of terminals and the communication unit,
In the competitive access section, the control unit receives one of the plurality of terminals when the communication unit receives a monitoring message that notifies the occurrence of a specific event from any one of the plurality of terminals. A control message including control contents of a controlled object group including the above terminals is configured to be transmitted from the communication unit to the one or more terminals as the controlled object group,
The control system, wherein the control message also serves as an affirmative response signal to the terminal that is the sender of the monitoring message. A communication unit that communicates with multiple terminals,
A control unit for controlling the communication unit,
The control unit generates a request message including a command for requesting a reply of each state with respect to a request target group including two or more terminals of the plurality of terminals, and the request message is the communication unit. Is configured to be transmitted to the plurality of terminals from
The control unit is configured to receive a response signal from the two or more terminals as the request target group in a time division system during a monitoring period after the transmission of the request message,
The monitoring period includes, in addition to the time slot for receiving the response signal, a contention access period used for communication between the plurality of terminals and the communication unit,
In the contention access section, the control unit stops transmission of the request message and stops transmission of the response signal from the two or more terminals as the request target group when a predetermined condition is satisfied. Is configured to
The predetermined condition is that the communication unit receives a monitoring telegram for notifying the occurrence of a specific event from any one of the plurality of terminals, and the time required for processing the specific event is a predetermined time. A control system characterized by being above. The time slot included in the monitoring period is a time slot for receiving the response signal, and is allocated only to one or more terminals included in the request target group. 5. The control system according to item 5. The control system includes one or more monitoring terminals included in the plurality of terminals,
The one or more monitoring terminals are configured to, when a specific event occurs, transmit a monitoring message for notifying the occurrence of the specific event to the communication unit,
7. The at least one monitoring terminal changes a waiting time until the monitoring message is transmitted at least in the contention access section according to the content of the specific event. The control system according to claim 1. The control system includes one or more monitoring terminals included in the plurality of terminals,
The one or more monitoring terminals are configured to, when a specific event occurs, transmit a monitoring message for notifying the occurrence of the specific event to the communication unit,
The at least one monitoring terminal changes the number of retries of carrier sense before transmission of the monitoring message according to the content of the specific event at least in the contention access section. 6. The control system according to any one of 6 above. The control system includes one or more monitoring terminals included in the plurality of terminals,
The one or more monitoring terminals are configured to, when a specific event occurs, transmit a monitoring message for notifying the occurrence of the specific event to the communication unit,
7. The one or more monitoring terminals change the number of times the monitoring message is retransmitted in accordance with the content of the specific event at least in the contention access section. The control system described in. The control system includes one or more monitoring terminals included in the plurality of terminals,
The one or more monitoring terminals are configured to, when a specific event occurs, transmit a monitoring message for notifying the occurrence of the specific event to the communication unit,
7. The one or more monitoring terminals change the transmission power of the monitoring message according to the content of the specific event at least in the contention access section, according to any one of claims 3 to 6. The control system described in.

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