JP2016009555A - Illumination system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform uniform control to a plurality of illuminations.SOLUTION: An illumination system has an illumination control device and illuminating devices. The illumination control device generates a control packet including control information for controlling dimming of each illuminating device and time information indicating a waiting time until each illuminating device starts dimming control, and transmits the generated control packet. The illuminating device receives the control packet, and waits for the waiting time indicated by the time information included in the received control packet, and then, performs the dimming control according to the control information.

Description

  The present invention relates to a lighting system.

  2. Description of the Related Art Conventionally, there is known a system that can efficiently use energy so as to avoid discomfort to the user by managing the energy of the entire building and finely controlling lighting, air conditioning, and the like. Such a system is called an energy management system (BEMS). In BEMS, lighting, air conditioning, and the like are automatically controlled by a management device. In addition, with respect to the lighting, the lighting device communicates with each other through short-distance wireless communication via a repeater to control dimming.

  However, the conventional technique has a problem that uniform control is difficult for a plurality of illuminations. In general, dimming control is performed by either collective control by broadcast or individual control by unicast. When dimming control is performed for an enormous number of lights, broadcast control is often used from the viewpoint of efficiency. However, even when performing collective control by broadcast, different control depending on the number and area of lighting to be controlled and control may be performed in multiple times, so dimming control for multiple lights A time difference occurs and uniform control becomes difficult.

  This invention is made | formed in view of the above, Comprising: It aims at providing the illumination system which can perform uniform control with respect to several illumination.

  In order to solve the above-described problems and achieve the object, an illumination system according to the present invention includes an illumination control device and an illumination device, and the illumination control device performs dimming of each of the illumination devices. A generating unit that generates control information including control information for controlling and time information indicating a waiting time until each lighting device starts dimming control, and a transmitting unit that transmits the generated control packet And the lighting device waits for a waiting time indicated by the time information included in the received control packet and a dimming control according to the control information. A dimming control unit for performing

  According to one aspect of the present invention, there is an effect that uniform control can be performed for a plurality of illuminations.

FIG. 1 is a diagram illustrating a system configuration example of the illumination system according to Embodiment 1. FIG. 2 is a block diagram illustrating a hardware configuration example of the illumination control device and the illumination device according to the first embodiment. FIG. 3 is a block diagram illustrating a functional configuration example of the illumination control device and the illumination device according to the first embodiment. FIG. 4 is a diagram illustrating a structure example of a control packet according to the first embodiment. FIG. 5 is a process sequence diagram illustrating an example of the flow of the illumination control process according to the first embodiment.

  Embodiments of an illumination system according to the present invention will be described below with reference to the accompanying drawings. In addition, this invention is not limited by the following embodiment.

(Embodiment 1)
[System Configuration According to Embodiment 1]
The system configuration of the illumination system according to Embodiment 1 will be described with reference to FIG. FIG. 1 is a diagram illustrating a system configuration example of the illumination system according to Embodiment 1.

  As illustrated in FIG. 1, the lighting system 10 includes a lighting control device 20 and a lighting device 30. The illumination control device 20 and the illumination device 30 are connected to a network 1 such as a PAN (Personal Area Network). In addition, the lighting system 10 includes a plurality of lighting devices 30 that are subject to dimming control.

  In the configuration described above, the lighting control device 20 generates a control packet for dimming control, and transmits the generated control packet to the lighting device 30. The lighting device 30 receives the control packet and performs dimming control according to the received control packet. The control packet is broadcast to a plurality of lighting devices 30. Here, the control packet may be divided into a plurality of broadcasts at different timings due to a large number of lighting devices 30 to be controlled. Even in such a case, the lighting control device 20 waits until the lighting control is performed after each lighting device 30 receives the control packet in order to execute the lighting control in each lighting device 30 almost simultaneously. Generate a control packet containing time.

  In addition to the standby time, the control packet includes various information used for dimming control such as dimming rate. The lighting device 30 waits for the designated waiting time based on the waiting time included in the control packet, and then performs dimming control based on the designated dimming rate and the like. As a result, the illumination system 10 can perform uniform control without causing a time difference in the light control for a plurality of illuminations. Details of the processing by the illumination control device 20 and the illumination device 30 will be described later.

[Hardware Configuration According to Embodiment 1]
Next, the hardware configuration of the illumination control device 20 and the illumination device 30 according to Embodiment 1 will be described with reference to FIG. FIG. 2 is a block diagram illustrating a hardware configuration example of the illumination control device 20 and the illumination device 30 according to the first embodiment. In addition, since the hardware configuration of the illumination control device 20 and the illumination device 30 is the same, the illumination control device 20 will be described as an example here.

  As shown in FIG. 2, the illumination control device 20 includes a CPU (Central Processing Unit) 22, a RAM (Random Access Memory) 23, a ROM (Read Only Memory) 24, and a communication I / F (Interface) 25. Have. These hardware are connected to the bus 21.

  The CPU 22 comprehensively controls the operation of the illumination control device 20. The CPU 22 controls the overall operation of the illumination control apparatus 20 by executing a program stored in the ROM 24 or the like using the RAM 23 as a work area (work area). The communication I / F 25 is an interface for communicating with an external device (for example, the lighting device 30).

[Functional configuration according to Embodiment 1]
Next, functional configurations of the illumination control device 20 and the illumination device 30 according to Embodiment 1 will be described with reference to FIG. FIG. 3 is a block diagram illustrating a functional configuration example of the illumination control device 20 and the illumination device 30 according to the first embodiment.

  As illustrated in FIG. 3, the lighting control device 20 includes a generation unit 210 and a transmission unit 220. The production | generation part 210 produces | generates the control packet containing the control information for controlling the light control of each illuminating device 30, and the time information which shows the waiting time until each illuminating device 30 starts dimming control. More specifically, when the control packet to be broadcast is divided into a plurality of pieces, the generation unit 210 calculates a standby time from when each lighting device 30 receives the control packet until the lighting control is started. And the production | generation part 210 produces | generates the control packet containing the control information regarding light control, such as the calculated standby | waiting time and a light control rate. The transmission unit 220 broadcasts the control packet generated by the generation unit 210.

  FIG. 4 is a diagram illustrating a structure example of a control packet according to the first embodiment. As shown in FIG. 4, the control packet includes information such as frame control, sequence number, destination PAN ID, destination PAN address, transmission source PAN address, MAC payload, and the like. The frame control includes frame control information such as the frame type of the MAC frame. The sequence number includes the sequence number of the packet data of the control packet to be transmitted.

  The destination PAN ID includes identification information in the PAN of the lighting device 30 that is the destination of the control packet. The destination PAN address includes an address in the PAN of the lighting device 30 that is the destination of the control packet. This destination PAN address is a broadcast address, and other control packets may include the same address. The transmission source PAN address includes an address in the PAN of the lighting control device 20 that is the transmission source of the control packet. The MAC payload includes dimming control information.

  For example, the MAC payload includes a command ID, the number of data, a standby time, a PAN address, a dimming rate, a dimming mode, and the like. Among these, the command ID, the number of data, and the waiting time are information common to the same control packet. The PAN address, dimming rate, and dimming mode are information for each lighting device 30. That is, in the MAC payload, the dimming rate and the dimming mode are specified for each PAN address of the lighting device 30 with respect to the command ID, the number of data, and the standby time.

  The command ID includes identification information of the MAC payload. The number of data includes the number of dimming control information, that is, the number of lighting devices 30 to be controlled. That is, there are as many PAN addresses, dimming rates, dimming modes, and the like as are included in the number of data. The standby time includes a standby time from when the lighting device 30 receives the control packet until the lighting control is performed. In this standby time, a different value is set for each control packet transmitted at different timings. The PAN address includes the address of the lighting device 30. Unlike the destination PAN address (broadcast address), this PAN address is an address unique to each lighting device 30. The dimming rate and dimming mode include information (control information) related to lighting dimming, and different information can be specified for each lighting device 30.

Here, an example of calculating the standby time will be described. The time (X) from the start of packet transmission from the lighting control device 20 to the start of dimming control in the lighting device 30 is obtained by (Equation 1).
Time until dimming control starts (X)
= Packet arrival time (S) + (number of transmissions (R _c ) −1) × transmission interval (R _i )
+ (Number of divided packets (D _n ) −transmission order (D _c )) × division packet transmission interval (D _i )
... (Equation 1)

The lighting control device 20 may transmit the same control packet a plurality of times in order to improve the reception rate of the control packet. In (Equation 1), “(number of transmissions (R _c ) −1) × transmission interval (R _i )” is for obtaining the time required to transmit the same control packet a plurality of times. That is, when the same control packet is transmitted a plurality of times, a value obtained by multiplying the transmission interval of the control packet by the number of transmission retries (number of transmissions (R _c ) −1) is obtained.

In addition, as described above, the lighting control device 20 may divide the control packet into a plurality of pieces and transmit them at different timings for the reason that the number of the lighting devices 30 is large. In (Equation 1), “(number of divided packets (D _n ) −transmission order (D _c )) × division packet transmission interval (D _i )” is divided into a plurality of control packets and transmitted at different timings. This is to obtain the time required for the process. In other words, when the control packet is divided into a plurality of pieces and transmitted at different timings, the remaining control after the transmission of the control packet is transmitted at the transmission interval of the divided control packet. A value obtained by multiplying the number of packets (number of divided packets (D _n ) −order of transmission (D _c )) is obtained.

Note that the time required for generating the control packet, the time required for extracting information from the control packet after reception, the time required for the lighting to be turned on after the dimming control is started, and the like can be considered. Since these are on the order of 10 ⁻³ seconds, these factors are negligibly small.

Further, the arrival time (S) of the packet is obtained by (Equation 2).
Packet arrival time (S) [msec]
= Transmission packet length [bytes] × 8 ÷ transmission speed [kbps] (Equation 2)

  The arrival time (S) of the packet is proportional to the transmission packet length because the time for propagation of the radio wave waveform in the atmosphere is negligibly small, although there is a delay due to the difference in transmission distance. When IEEE802.15.4 is used for short-range wireless communication between the lighting control device 20 and the lighting device 30, the transmission speed is 250 kbps. For example, when the transmission packet length is data of 127 bytes, the arrival time (S) of the packet is “127 × 8 ÷ 250 = 4.064 [msec]”.

From (Equation 1) and (Equation 2), the waiting time (T) from when each lighting device 30 receives the control packet until when the lighting control is actually started is obtained by (Equation 3).
Standby time (T)
= Constant (X _max ) _-Time until light control is started (X) (Equation 3)

Here, the constant (X _max ) takes such a value that the waiting time (T) does not become negative. The constant (X _max ) is obtained by (Equation 4).
Constant (X _max )
= Maximum packet arrival time (S _max )
+ (Maximum number of transmissions (R _cmax ) −1) × transmission interval (R _i )
+ Maximum value of the number of divided packets (D _nmax ) × Divided packet transmission interval (D _i )
... (Equation 4)

In (Equation 4), the transmission interval (R _i ) and the transmission interval (D _i ) of the divided packets are constants given as set values. The transmission interval (R _i ) is set based on a time during which one packet can be sufficiently transmitted. For example, the transmission interval (R _i ) may be set to about 20 msec if one packet length is about 250 bytes. Further, the transmission interval (D _i ) of the divided packets is a value obtained by multiplying the transmission interval (R _i ) by the maximum value of the number of transmissions. For example, the transmission interval (D _i ) of the divided packets may be set to about 100 msec if the maximum number of transmissions (R _cmax ) is five.

Further, the number of divided packets (D _n ) varies depending on the number of lights to be controlled, but the number of lights managed by the lighting system 10 is determined in advance during operation. Therefore, in (Expression 4), the maximum value (D _nmax ) of the number of divided packets can be a constant. Further, the maximum value (S _max ) of packet arrival time can be set to a fixed value by determining the maximum packet length to be transmitted. From these, the constant (X _max ) is determined in advance when the illumination system 10 is built.

That is, when generating the control packet, the generation unit 210 of the lighting control device 20 calculates the time (X) until the dimming control is started, and the time until the calculated dimming control is started ( The standby time (T) is obtained from X) and a constant (X _max ). And the production | generation part 210 produces | generates a control packet by setting the calculated | required waiting time (T) to the MAC payload contained in a control packet, and setting the various information contained in a control packet. For example, assuming that one packet is 250 bytes, the maximum number of transmissions is 3, the transmission interval is 20 msec, the transmission interval of divided packets is 100 msec, and the maximum value of the number of divided packets is 5, the constant (X _max ) is “250 × 8 ÷ 250 + (3-1) × 20 + 5 × 100 = 548 msec ”.

  Returning to the description of FIG. 3, the lighting device 30 includes a receiving unit 310 and a dimming control unit 320. The receiving unit 310 receives a control packet broadcast by the lighting control device 20. As described above, the control packet is transmitted to the destination PAN address that is a broadcast address. That is, all the lighting devices 30 belonging to the network set as the destination PAN ID receive the control packet.

  The dimming control unit 320 performs dimming control according to the control packet received by the receiving unit 310. More specifically, the dimming control unit 320 confirms the MAC payload included in the control packet received by the receiving unit 310. Then, the dimming control unit 320 confirms the PAN address included in the MAC payload, and searches for an address that matches the PAN address of the lighting device 30 (its own lighting device 30). At this time, the dimming control unit 320 confirms the standby time included in the MAC payload when an address that matches the PAN address of the dimming control unit 320 is included in the MAC payload. Thereafter, the dimming control unit 320 waits for the designated waiting time and then performs dimming control based on the dimming rate and the dimming mode. The dimming control unit 320 ends the process without performing dimming control when the MAC payload does not include an address that matches the PAN address of the dimming control unit 320.

[Lighting Control Processing According to Embodiment 1]
Next, the flow of the illumination control process according to Embodiment 1 will be described with reference to FIG. FIG. 5 is a process sequence diagram illustrating an example of the flow of the illumination control process according to the first embodiment.

  As illustrated in FIG. 5, the lighting control device 20 calculates a standby time from when each lighting device 30 receives the control packet until the lighting control is started, and controls the calculated standby time and the lighting control. A control packet including control information and the like is generated (step S101). And the lighting control apparatus 20 transmits the produced | generated control packet with respect to each lighting apparatus 30 by broadcast (step S102). The transmission of the control packet to each lighting device 30 is performed to the destination PAN address that is a broadcast address. The control packet divided into a plurality is transmitted at the transmission interval of the divided packets. In addition, the control packet may be transmitted a plurality of times in order to improve the reception rate of the control packet of each lighting device 30.

  The lighting device 30 receives the control packet transmitted by the lighting control device 20 (step S103). And the illuminating device 30 confirms the PAN address contained in a control packet, and when the address which corresponds with an own PAN address exists, it waits only for the designated waiting time (step S104). Subsequently, the lighting device 30 performs dimming control based on the dimming rate and dimming mode included in the control packet (step S105). The processing by the lighting device 30 described above is performed by each lighting device 30.

[Effects of Embodiment 1]
When generating a control packet for causing the lighting device 30 to perform dimming control, the lighting control device 20 calculates and calculates a standby time from when the lighting device 30 receives the control packet until the lighting control is started. A control packet including the waiting time is generated, and the generated control packet is broadcast. The lighting device 30 receives the control packet broadcast by the lighting control device 20, waits for a waiting time according to the control packet corresponding to itself, and performs dimming control. As a result, the illumination system 10 can suppress a time difference generated by dimming control for a plurality of illuminations, and can perform uniform control for the plurality of illuminations.

  Moreover, since the illumination system 10 broadcasts a control packet including destination information for each illumination device 30 and control information for controlling dimming, the dimming control by each illumination device 30 is performed even in the broadcast. Can be specified individually.

(Embodiment 2)
Now, although the embodiment of the illumination system 10 according to the present invention has been described so far, the present invention may be implemented in various different forms other than the above-described embodiment. Therefore, different embodiments of (1) standby time, (2) configuration, and (3) program will be described.

(1) Standby time In the above-described embodiment, a case has been described in which the same control packet is transmitted a plurality of times and one control packet is transmitted in a plurality of portions in the transmission of the control packet. In addition, for the calculation of the waiting time included in such a control packet, the time required to transmit the same control packet multiple times and the time required to transmit one control packet divided into a plurality of times, The case where it is included in the waiting time was explained. Such waiting time may include any of the above-mentioned times. For example, the waiting time may include at least the time required for transmitting one control packet in a plurality of parts. Specifically, in (Equation 1), “(number of transmissions (R _c ) −1) × transmission interval (R _i )” may not be used for calculating the standby time. In addition to this, the standby time excluding the arrival time (S) of the packet may be calculated. As described above, even when any information is used for calculating the standby time, more uniform control can be performed for a plurality of lights as compared with the conventional technique in which collective control is performed by broadcasting. Can do.

(2) Configuration In addition, information including processing procedures, control procedures, specific names, various data, parameters, and the like shown in the documents and drawings can be arbitrarily changed unless otherwise specified. Each component of the illustrated apparatus is functionally conceptual and does not necessarily need to be physically configured as illustrated. That is, the specific form of the distribution or integration of the devices is not limited to the illustrated one, and all or a part of the distribution or integration is functionally or physically distributed or arbitrarily in any unit according to various burdens or usage conditions. Can be integrated.

(3) Program The program executed in the lighting control device 20 or the lighting device 30 is, as one form, a file in an installable format or an executable format, a CD-ROM, a flexible disk (FD), a CD- The program is recorded on a computer-readable recording medium such as R and DVD (Digital Versatile Disk). The program executed by the lighting control device 20 and the lighting device 30 may be stored on a computer connected to a network such as the Internet and provided by being downloaded via the network. Moreover, you may comprise so that the program performed with the illumination control apparatus 20 or the illumination apparatus 30 may be provided or distributed via networks, such as the internet. Moreover, you may comprise so that the program performed with the illumination control apparatus 20 or the illumination apparatus 30 may be provided by previously incorporating in ROM etc.

  The program executed by the illumination control device 20 and the illumination device 30 has a module configuration including the above-described units (the generation unit 210, the transmission unit 220, the reception unit 310, and the dimming control unit 320). As the CPU (processor) reads the program from the storage medium and executes it, each unit is loaded onto the main storage device, and the generation unit 210, the transmission unit 220, the reception unit 310, and the dimming control unit 320 are the main units. It is generated on a storage device.

DESCRIPTION OF SYMBOLS 10 Illumination system 20 Illumination control apparatus 30 Illumination apparatus 210 Generation part 220 Transmission part 310 Reception part 320 Dimming control part

JP 2011-0665825 A JP 2011-0665826 A JP, 2014-032807, A

Claims (5)

A lighting system having a lighting control device and a lighting device,
The lighting control device includes:
A generating unit that generates control packets including control information for controlling dimming of each of the lighting devices and time information indicating a waiting time until each of the lighting devices starts dimming control;
A transmission unit for transmitting the generated control packet,
The lighting device includes:
A receiving unit for receiving the control packet;
A lighting system comprising: a dimming control unit that performs dimming control according to the control information after waiting for a standby time indicated by the time information included in the received control packet.   The generation unit, when dividing one control packet into a plurality of pieces, calculates the waiting time from the number of control packets to be divided and the order of transmission of the control packets. The illumination system according to 1.   The said generation part calculates the said standby | waiting time from the frequency | count of transmission of the said control packet, and a transmission interval, when transmitting the same said control packet in multiple times. Lighting system.   The lighting system according to claim 1, wherein the generation unit calculates the waiting time from a packet length of the control packet and a transmission speed at which the control packet is transmitted. . The generating unit generates the control packet including a broadcast address and a different address in each of the lighting devices,
The transmission unit broadcasts the generated control packet,
The receiving unit receives the control packet corresponding to the broadcast address of the lighting device;
The dimming control unit performs dimming control according to the control information after waiting for a waiting time indicated by the time information when the address of the own device is included in the received control packet. The illumination system according to any one of claims 1 to 4, wherein

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