JP3979117B2 - Lighting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a lighting device that can remotely control a lighting state of a lighting fixture mainly in a general house.
[0002]
[Prior art]
2. Description of the Related Art In recent years, there has been provided a lighting device that can switch the lighting state of a lighting fixture by a remote control device using a wireless signal using infrared as a transmission medium. In this technology, the user needs to operate the remote control device toward the lighting fixture, and since infrared rays do not pass through the wall, the lighting fixture in another room cannot be controlled by the remote control device over the wall.
[0003]
On the other hand, there are also lighting fixtures that are provided with human sensors or brightness sensors in the lighting fixtures so that the lighting fixtures are automatically turned on when the surroundings are dark, or that the lighting fixtures are turned on only when there is a person in the room Proposed. Since the lighting fixture provided with such a sensor can be automatically turned on and off, it has the advantage of saving energy by preventing forgetting to turn off and suppressing wasteful power consumption. However, in this type of lighting fixture, the lighting fixture with a built-in sensor operates alone, and the lighting fixture without a sensor cannot reflect the operation of the lighting fixture with a sensor.
[0004]
If there are a plurality of lighting fixtures provided with the remote control device as described above in the house, for example, when going out all at once when going out, the remote control device must be operated for each lighting fixture. When the number of instruments increases, the operation of the remote control device becomes troublesome. In order to solve this kind of problem, it is conceivable to arrange switches for changing the lighting state of the lighting fixtures in one place in the house so that the power supply operation can be performed collectively. Wiring is concentrated in one place, and it is difficult to perform this kind of construction in an existing house unless it is a new house.
[0005]
[Problems to be solved by the invention]
In order to solve the problem that the remote control device as described above can only control the lighting fixtures individually, it is conceivable to use radio waves as a transmission medium between the remote control device and the lighting fixtures. If radio waves are used as a transmission medium, it is possible to control lighting fixtures in other rooms over the wall, and thus it is possible to control a plurality of lighting fixtures collectively with a single remote control device. In addition, the use of wireless technology in a luminaire provided with a sensor makes it possible to correlate the operation of the luminaires.
[0006]
However, since the remote control device that has been widely used uses infrared as a transmission medium, if the transmission medium is a radio wave, it is necessary to use dedicated products for both the luminaire and the remote control device, which increases the cost. Arise. Moreover, since it reaches beyond the line of sight when using radio waves, it must be transmitted with an identification code so that interference does not occur. Even with the identification code alone, the data length becomes large. As a result, the time required for transmission becomes longer, and the response time for the operation is delayed.
[0007]
The present invention has been made in view of the above-mentioned reasons, and the object thereof is to enable a plurality of lighting fixtures to be collectively controlled while using an off-the-shelf lighting fixture, and to control with good responsiveness. An object of the present invention is to provide an illuminating device that makes it possible.
[0008]
[Means for Solving the Problems]
  The invention of claim 1 is a remote control device that remotely controls the lighting state of the lighting fixture and is given an identification code, manages the identification code of the remote control device, and lights up the lighting fixture via the remote control device. And a transmission path that transmits a signal including an identification code as a transmission medium that is at least part of a communication path that passes through the remote control device between the management apparatus and the lighting fixture,The remote control device can communicate with the management device in both directions, and can communicate with the master controller in both directions via the transmission path, and the identification code is set in association with the lighting fixture. The master controller specifies the remote control device identification codes associated with the lighting fixtures to be controlled in a batch and sends a signal including the instruction contents. After controlling the lighting fixtures, send a signal specifying the individual identification code of the remote control device associated with the lighting fixture to be controlled to confirm receipt of the instruction contents, and the remote control device designates the individual identification code When a received signal is received, a response is sent back to the master controllerIt is characterized by that.
[0014]
  In the invention of claim 2, claim 1 is provided.In the invention, the master controller is associated with a lighting fixture to be controlled.The remote control deviceWhen the response from the camera cannot be received, the identification code to be controlled is collectively specified and the signal including the instruction content is transmitted, and then associated with the lighting fixture to be controlled.Remote control deviceThe process of transmitting a signal designating each individual identification code is repeated.
[0015]
  In the invention of claim 3, claim 1 is provided.In the invention, the master controller is associated with a lighting fixture to be controlled.The remote control deviceI could not receive a response when I could not receive a response fromRemote control deviceAfter specifying the identification code and sending a signal containing the instruction content,Remote control deviceThe process of transmitting a signal designating an identification code is repeated.
[0016]
  In the invention of claim 4, claim 1 is provided.In the invention ofThe remote control deviceAre provided, and the master controllerRemote control deviceWithin a specified time limit after sending a signal specifying the individual identification codeRemote control deviceWhen a response from is returned, or when the specified time limit expires without a response being returned,Remote control deviceA signal designating an identification code is transmitted.
[0017]
  In the invention of claim 5, claim 1 is provided.In the invention, the master controller isThe remote control deviceAfter sending a signal specifying the individual identification code ofRemote control deviceWhen a response from is not returned, it is determined that communication is abnormal and is notified.
[0018]
  In the invention of claim 6, claim 1 is provided.In the invention, the master controller isThe remote control deviceAfter sending a signal specifying the individual identification code ofRemote control deviceWhen a response from is not returnedRemote control deviceIs notified to the management device.
[0019]
  In the invention of claim 7, claim 5 is provided.In the invention of the above, the master controller and theRemote control deviceAny one of the management device and the lighting fixture includes a notification unit that notifies communication abnormality.
[0020]
  In the invention of claim 8, claims 1 to 7 are provided.In the invention, the management device is connected to an external network, and information held by the management device can be transferred to a terminal on the network.
[0021]
  In the invention of claim 9, claim 1 is provided.The inventionBeforeThe identification code is composed of an ID unique to the remote control device and a shortened ID whose data length is shorter than the ID and which allows the management device to identify the remote control device under management, and the source of the signal passing through the transmission path Is specified by the ID, and the transmission destination is specified by the abbreviated ID.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
In the present embodiment, the configuration shown in FIG. 1 will be described as an example. In the illustrated example, three types of lighting fixtures 1a to 1c are provided.
[0023]
The lighting fixture 1a is remotely controlled by a wireless signal from the remote control device 2 in the lighting state. Infrared rays are used as a transmission medium for data transmitted between the remote control device 2 and the lighting fixture 1a and instructing control contents. Further, between the remote control device 2 and the lighting fixture 1a, data is transmitted in one direction from the remote control device 2 toward the lighting fixture 1a. The lighting fixtures 1b and 1c are remotely controlled by a master controller 3 provided separately from the remote controller 2. Here, as the lighting state, in addition to lighting / extinguishing, well-known lighting states such as step dimming or continuous dimming, fade-in / fade-out, and blinking lighting can be appropriately employed.
[0024]
The master controller 3 bi-directionally transmits data to and from the remote control device 2 using radio waves (specific low power radio) as a transmission medium. The master controller 3 can transmit data instructing the lighting state of the luminaire 1a to the remote controller 2. By using radio waves as a data transmission medium, the master controller 3 can transmit data to all remote controllers 2 in the home if it is a general home. On the other hand, data can be transmitted from one master controller 3. In other words, since the radio wave as a transmission medium passes through the walls in the house, if one master controller 3 is installed in the house (a plurality if necessary), data from the master controller 3 is transmitted to all remote controllers in the house. 2 can be transmitted. The remote control device 2 used in the present embodiment receives data transmitted from the master controller 3 using radio waves as a transmission medium, and transmits the data to the luminaire 1a by converting the transmission medium into infrared rays. Therefore, the master controller 3 can collectively control all the lighting fixtures 1 a in the entire house through the remote controller 2. Here, since the luminaire 1a uses infrared light that is widely used as a transmission medium, the conventional luminaire 1a can be used if the transmission format of the infrared signal when transmitting data from the remote control device 2 is not changed. The functions of this embodiment can be provided for the manufacturer without newly designing the lighting fixture 1a, and the functions of the present embodiment can be provided for the user without purchasing a new lighting fixture 1a. Can be enjoyed.
[0025]
  By the way, the master controller 3 can also control the lighting state of the lighting fixtures 1 b and 1 c without passing through the remote control device 2. The lighting fixture 1 b performs data transmission with the infrared transmission medium with the master controller 3, and the lighting fixture 1 c performs data transmission with the master controller 3 with radio waves as the transmission medium. That is, the luminaire 1b is arranged in a place where data is transmitted in one direction from the master controller 3 to the luminaire 1b using infrared rays as a transmission medium, and infrared rays can be transmitted to and from the master controller 3 in the house. The In addition, the lighting fixture 1c transmits data bidirectionally using radio waves as a transmission medium, and it is possible to control the lighting state from the house even if it is installed outdoors. Therefore, if the luminaires 1a and 1b are installed in the house and the luminaire 1c is installed outdoors, the master controller 3 is used to install the luminaires 1a and 1b installed in the house and the luminaire installed outdoors. It becomes possible to control the lighting state collectively for both 1c. Like the master controller 3 and the remote control device 2, the master controller 3 and the lighting device 1 c can communicate bidirectionally using radio waves as a transmission medium, and both the lighting fixture 1 c and the remote control device 2 are lighting fixtures. Associated withThe NoRegardless, the remote control device 2 and the master controller 3 enable remote control of the lighting fixtures 1a to 1c, and constitute a remote control device.
[0026]
The master controller 3 of this embodiment is connected to the server 4 via a wired transmission path. The server 4 is configured using, for example, a personal computer, the master controller 3 is connected to an RS-232C standard interface capable of serially transmitting data, and transmits data to and from the master controller 3 in both directions. . The server 4 can give data to the master controller 3 and can acquire data held by the master controller 3. Further, the server 4 can bidirectionally transmit data to and from the terminal 6 via the network NT such as the Internet. The data acquired by the server 4 can be confirmed by the terminal 6, or the terminal 6 can send data to the server 4. It is possible to transmit data.
[0027]
Thus, if the server 4 sets a time schedule for controlling the lighting states of the lighting loads 1a to 1c, the lighting states of the lighting fixtures 1a to 1c can be controlled according to the time schedule via the master controller 3. For example, it is possible to control illumination decoratively by installing a large number of lighting fixtures 1c outdoors. Further, if the server 4 is installed in a living room or the like, and the server 4 is manually operated to give an instruction to the master controller 3, it is possible to control all the lighting fixtures 1a to 1c in the house and outdoors from the living room. become.
[0028]
On the other hand, since the server 4 can transmit data to and from the terminal 6 through the network NT, it is also possible to instruct the lighting state of the lighting fixtures 1a to 1c from the terminal 6 to the server 4. Information held by the master controller 3 that manages the lighting states of the appliances 1 a to 1 c can be monitored by the terminal 6 via the server 4. That is, by operating the terminal 6, the lighting states of the lighting fixtures 1a to 1c can be set from outside the house. Moreover, by monitoring the lighting state of the luminaires 1a to 1c from outside the house, it can be used for crime prevention by judging the existence of a person in the premises, or confirming that the luminaires 1a to 1c are forgotten to be turned off to ensure safety. It becomes possible.
[0029]
Now, it is assumed that the lighting of all the lighting fixtures 1a to 1c is instructed by the server 4. In this case, the server 4 serially transmits lighting instructions for all the lighting fixtures 1 a to 1 c to the master controller 3. The master controller 3 instructs the lighting fixture 1b to turn on by an infrared signal, and instructs the lighting fixture 1c to turn on the radio wave as a transmission medium. Further, the master controller 3 also instructs the remote controller 2 to turn on using radio waves as a transmission medium, and the remote controller 2 that has received the lighting instruction instructs each lighting fixture 1a to turn on by an infrared signal. It becomes possible to light all the lighting fixtures 1a-1c in such a procedure.
[0030]
Here, a schematic configuration of each component of the above-described embodiment will be described. The lighting fixtures 1a to 1c basically have the same configuration, and as shown in FIG. 2, the lighting fixtures 1a to 1c include a control unit 10 having a microprocessor as a main component, and the control unit 10 has a lighting load with respect to the load control unit 11. Indicates the lighting state of. The load control unit 11 includes a lighting load lighting circuit, and lighting lamps can be turned on / off, dimmed, and fade-in / fade-out controlled by instructions from the control unit 10. A communication unit 12 is connected to the control unit 10 and transmits data to and from the remote control device 2 or the master controller 3 through the communication unit 12. In the lighting fixtures 1 a and 1 b, the communication unit 12 is configured to receive an infrared signal, receives the infrared signal from the remote controller 2 or the master controller 3, and inputs data to the control unit 10. Moreover, in the lighting fixture 1c, the communication part 12 is the structure which transmits / receives an electromagnetic wave, Comprising: Not only can it receive the data from the master controller 3, but it can notify the lighting state of lighting load with respect to the master controller 3. It has become.
[0031]
As described above, since the lighting states of the lighting fixtures 1a to 1c are remotely controlled, instructions are given to the lighting fixtures 1a to 1c so that the lighting states of the lighting fixtures 1a to 1c are not illegally changed. It is necessary to confirm the correctness of the apparatus and to identify which lighting apparatus 1a to 1c is the instruction. Therefore, a storage unit 13 is provided that stores an ID (described later) as an identification code of a device that is permitted to give instructions to the lighting fixtures 1a to 1c. The storage unit 13 also stores a shortened ID, which will be described later, as an identification code. When the lighting device 1a to 1c is instructed to turn on the lighting fixtures 1a to 1c from the remote controller 2 or the master controller 3, the ID of the remote controller 2 or the master controller 3 is transmitted together with data as will be described later. 12 is compared with the ID (or abbreviated ID) stored in the storage unit 13 to determine whether or not to accept data. Function data that determines the operation of the control unit 10 is also registered in the storage unit 13, and the control unit 10 controls the function of the load control unit 11 by setting the function data. That is, as described above, the load control unit 11 can control the lighting load on / off, dimming, and fade-in / fade-out, and all the programs for performing these controls are the control unit 10. The operation of the control unit 10 is determined by setting in the storage unit 10 a flag that specifies which program is used. The storage unit 13 desirably retains the stored contents even when there is no power supply, and needs to be rewritable, so it is desirable to use an EEPROM.
[0032]
Furthermore, the lighting fixtures 1a to 1c are provided with an operation unit 14 including a switch for setting the storage content of the storage unit 13 and a display unit 15 for confirming the content set in the storage unit 13. By the operation of the operation unit 14, it is possible to store the function data regarding the ID of the remote controller 2 and the master controller 3 and the operation of the lighting fixtures 1 a to 1 c in the storage unit 13. That is, the operation unit 14 can register the ID of the remote controller 2 or the master controller 3 that can give instructions to the lighting fixtures 1a to 1c, or can delete the registered ID. Further, the setting content in the operation unit 14 is displayed on the display unit 15. The display unit 15 may be anything as long as the setting content of the operation unit 14 can be confirmed. For example, a liquid crystal display is used. Further, not only the setting content of the operation unit 14 but also the communication state by the communication unit 12 and the content of abnormality at the time of abnormal operation of the lighting fixtures 1a to 1c may be displayed together. Is used. The lighting fixtures 1a to 1c are supplied with power from a commercial power source, and are converted into electric power necessary for driving an internal circuit in the power source unit 17.
[0033]
Here, you may provide the sensor part 16 provided with at least one of a human sensitive sensor and a brightness sensor in the lighting fixtures 1a-1c. A human sensor can be realized at a low cost by using a passive sensor that detects a heat ray emitted from a human body using a pyroelectric element, but transmits a detection wave such as an infrared ray or an ultrasonic wave to a monitoring space. In addition, an active type that detects the presence / absence of a human body in the monitoring space using the relationship between infrared waves or ultrasonic waves received from the monitoring space and detection waves may be used. This type of sensor includes a human sensor known as an infrared sensor, a distance measuring sensor, an ultrasonic sensor, or the like. As the brightness sensor, a sensor that converts ambient brightness into an electric signal using a photoelectric element such as CdS or a photodiode is used.
[0034]
Since the lighting fixtures 1a and 1b transmit data in one direction from the remote controller 2 or the master controller 3, the output of the sensor unit 16 is used inside the lighting fixtures 1a and 1b. For example, when a human sensor is used, the lighting load is turned on when a human is detected by the human sensor, and then illumination is performed when no human is detected even after a specified time has elapsed since the human was no longer detected. Control to turn off the load becomes possible. In addition, when the lighting load is turned on / off according to the human detection by the human sensor, and the lighting load does not need to be turned on in the daytime, the human sensor is combined with the brightness sensor. The illumination load may be turned on only while the condition that the surrounding is dark and the person is detected is satisfied. When the lighting load is turned on / off in response to only the surrounding brightness regardless of the presence or absence of a person, the sensor unit 16 is provided with only the brightness sensor.
[0035]
On the other hand, since the luminaire 1c can bidirectionally transmit data to and from the master controller 3, in addition to the same control as the luminaires 1a and 1b, the output of the sensor unit 16 is transferred to the master controller 3. Is also possible. For example, it is possible to transmit information obtained from the output of the human sensor or the brightness sensor to the master controller 3 and transmit data to the lighting fixtures 1 a to 1 c under the control of the master controller 3. To explain an example, when it is detected that the surrounding has become dark by the output of the brightness sensor provided in the lighting fixture 1c, the other lighting fixtures 1a and 1b can be turned on by notifying the master controller 3. It becomes possible. The timing at which the output of the sensor unit 16 is transmitted to the master controller 3 may be a point in time when there is a change in the presence or absence of a person if it is a human sensor, and may be a specified cycle if it is a brightness sensor.
[0036]
As shown in FIG. 3, the remote control device 2 includes a control unit 20 having a microprocessor as a main component, and the control unit 20 transmits an infrared signal to the luminaire 1 a through the communication unit 22. The communication unit 22 can perform bidirectional data transmission with the master controller 3 using radio waves as a transmission medium. The remote control device 2 can transmit data between the lighting fixture 1a and the master controller 3, and stores an ID set for each remote control device 2 and an ID of the master controller 3 allowed as a communication partner. A storage unit 23 is connected to the control unit 20. The storage unit 23 also stores a short ID described later. The storage unit 23 uses an EEPROM because it needs to be able to hold the stored contents and be rewritable even when there is no power supply.
[0037]
Further, the remote control device 2 is provided with an operation unit 24 including a switch for setting the storage content of the storage unit 23 and a display unit 25 for confirming the content set in the storage unit 23. By operating the operation unit 24, the ID of the remote control device 2 and the ID of the master controller 3 can be stored in the storage unit 23. That is, the operation unit 24 can register the IDs of the remote control device 2 and the master controller 3 or delete the registered IDs. Further, the setting content in the operation unit 24 is displayed on the display unit 25. The display unit 25 may be anything as long as the setting content of the operation unit 24 can be confirmed. For example, a liquid crystal display is used. Further, not only the setting content of the operation unit 24 but also the communication state by the communication unit 22 and the content of abnormality when the operation of the remote control device 2 is abnormal may be displayed together. A light emitting diode is used for this kind of display. ing. The power supply unit 27 of the remote control device 2 uses a battery as a power source. However, if it is not necessary to make the remote control device 2 portable, power may be supplied from a commercial power source and converted into power necessary for driving the internal circuit in the power supply unit 27.
[0038]
Similarly to the lighting fixtures 1a to 1c, the remote controller 2 can also be provided with a sensor unit 26 including at least one of a human sensor and a brightness sensor. When the sensor unit 26 is provided in the remote control device 2, the sensor unit 26 is not provided in the lighting fixtures 1a to 1c, or only one of the human sensor and the brightness sensor is provided in the lighting fixtures 1a to 1c. It is desirable to provide the other on the remote control device 2. Since the output of the sensor unit 26 can be transferred to the master controller 3, it can be used for controlling the lighting fixtures 1 a to 1 c managed by the master controller 3, and each lighting fixture 1 a to 1 under the management of the master controller 3. It is also possible to transmit the output of the sensor unit 26 to 1c.
[0039]
The master controller 3 has a configuration shown in FIG. 4 and includes a control unit 30 having a microprocessor as a main component. The control unit 30 transmits and receives data to and from the remote control device 2 through a communication unit 32 by radio waves. Data is transmitted bidirectionally between the server 4 and the server 4 by wired serial transmission. Further, the communication unit 32 of the master controller 3 can perform unidirectional data transmission with the luminaire 1b using infrared rays as a transmission medium, and bidirectional data transmission with the luminaire 1c using radio waves as a transmission medium. Is possible. Similarly to the remote controller 2, the master controller 3 has a storage unit 33 for storing the ID for identifying the master controller 3 and the IDs of the remote controller 2 and the server 4 that are allowed as communication partners. Connected. The storage unit 33 also stores a short ID described later. The storage unit 33 uses an EEPROM so that the stored contents can be retained and rewritten even when no power is supplied.
[0040]
The master controller 3 is provided with an operation unit 34 including a switch for setting the storage content of the storage unit 33 and a display unit 35 for confirming the content set in the storage unit 33. Here, since the master controller 3 manages the plurality of lighting fixtures 1a to 1c, the number of switches constituting the operation unit 34 is relatively large. By operating the operation unit 34, the ID of the master controller 3 and the ID of the remote control device 2 can be stored in the storage unit 33. The operation unit 34 enables registration and deletion of the contents of the storage unit 33. Further, the setting content in the operation unit 34 is displayed on the display unit 35. The display unit 35 may be of any type as long as the setting content of the operation unit 34 can be confirmed, but a configuration capable of displaying characters and graphics is desirable. For example, a liquid crystal display is used. In addition, an abnormality such as a failure can be reported on the liquid crystal display, but if a light emitting diode is used in combination as a means for notifying the abnormality, the abnormality can be easily recognized. The power supply unit 37 of the master controller 3 may use a battery as a power supply, but it is desirable that power be supplied from a commercial power supply and converted into power necessary for driving the internal circuit in the power supply unit 37.
[0041]
The server 4 is configured using a personal computer as described above. That is, as shown in FIG. 5, the server 4 includes a control unit 40 having a microprocessor as a main component, and a communication unit 42 that can be connected to the master controller 3 and the network NT is connected to the control unit 40. The server 4 includes information acquired from the master controller 3 regarding the operating state of the lighting fixtures 1a to 1c and the remote control device 2 under the control of the master controller 3 (ID, abbreviated ID to be described later, and the name given to the lighting fixtures 1a to 1c Etc.) and a data / program storage unit 43 for storing operational error contents, and a data processing unit 41 for storing a program capable of setting a shortened ID and processing for handling operational errors, which will be described later. Prepare.
[0042]
The server 4 includes an operation unit 44 including a keyboard, and can perform various settings for the managed lighting fixtures 1a to 1c, the remote control device 2, and the master controller 3, and can transmit a desired command. Further, a display unit 45 is provided so that the contents of various settings by the server 4 can be displayed and the contents of the trouble can be notified when the trouble occurs. A CRT or a liquid crystal display is used for the display unit 45.
[0043]
The terminal 6 only needs to be accessible to the server 4 via the network NT. For example, a mobile phone, a personal computer, a PDA, or the like can be used. Therefore, general-purpose packet data or a tone signal can be used as a data transmission form. In some cases, it is also possible to transmit data between the terminal 6 and the server 4 in the form of an e-mail.
[0044]
Next, a data transmission mode between each component will be described. First, an operation of transmitting data by radio waves using the master controller 3 as a transmission source and the remote control device 2 as a transmission destination will be described. That is, as shown in FIG. 6A, the master controller 3 is an operation for controlling the lighting state of the lighting fixture 1a (see FIG. 1) through the remote controller 2, and as shown in FIG. In addition to the data DAT for instructing the lighting state of the appliance 1a, a signal including the ID (ID1) of the master controller 3 and the ID (ID2) of the remote controller 2 is transmitted. According to the Japan Radio Industry Association Standard-T67 Notification / H6 No. 424, the identification code of the low power communication system is required to be composed of 48 bits. Therefore, in order for the master controller 3 to transmit the data DAT to the lighting apparatus 1a through the remote controller 2, two IDs (ID1, ID2) of the transmission source and the transmission destination are required in addition to the data DAT. A minimum of 96 bits is required.
[0045]
The example shown in FIG. 6 is a case where the master controller 3 transmits data DAT to one remote control device 2, but in the case where the lighting states of a plurality of lighting fixtures 1a in the house are collectively controlled, FIG. As shown in (a), the master controller 3 transmits data DAT to a plurality of (three in the illustrated example) remote control devices 2. That is, since there are a plurality of transmission destinations with the master controller 3 as a transmission source, IDs (ID21, ID22, ID23) corresponding to the number of transmission destinations are required. Accordingly, as shown in FIG. 7B, the transmission destination IDs are added for the number of transmissions, and the bit length of the signal transmitted from the master controller 3 is (48 bits + 48 bits × the number of transmission destinations + data). Bit number). In other words, if all the remote control devices 2 under the control of the master controller 3 try to instruct to send out an infrared signal instructing to turn on the luminaire 1a, the bit length of the signal sent from the master controller 3 is very large. The problem of lengthening arises.
[0046]
In practice, in order to increase the reliability of signal transmission, the ID included in the signal transmitted from the master controller 3 is divided into a plurality of pieces as shown in FIG. Therefore, even if the ID itself is 48 bits, the bit length corresponding to one ID in the signal is longer than 48 bits. In the example shown in FIG. 8, in order to transmit 48-bit data, it is divided into 7 bits × 6 + 6 bits, and a 1-bit checksum C is added to each divided portion, and a 1-bit checksum as a whole. Since C is added, the checksum C requires 8 bits, for a total of 56 bits.
[0047]
As described above, when the number of bits of the signal transmitted from the master controller 3 to the remote control device 2 increases, the time required for transmission increases, and as a result, the time for the master controller 3 to occupy the transmission path to the remote control device 2 increases. Become.
[0048]
In order to solve such a problem, in the present embodiment, apart from the original ID of the remote controller 2, a shortened ID that is associated with each ID on a one-to-one basis and has a bit length smaller than the original ID is set. By giving an instruction to the remote control device 2 using the shortened ID, the occupation time of the transmission path can be shortened. Further, as described above, since the master controller 3 is managed by the server 4 in the present embodiment, the short ID associated with the ID of the master controller 3 is also used when specifying the master controller 3 from the server 4. . That is, in the case where a plurality of master controllers 3 are provided, the transmission time of the signal transmitted from the server 4 to the master controller 3 is long as well as the signal transmitted from the master controller 3 to the remote controller 2. Problem arises. This is because the server 4 and the master controller 3 are connected by wire, and a 48-bit ID is not required for data transmission from the server 4 to the master controller 3, but the master controller 3 is connected to the remote controller 2. Since the ID of the master controller 3 is 48 bits in order to transmit data by radio waves, the destination is designated as a 48-bit ID when transmitting data from the server 4 to the master controller 3 as a result. Because you have to do it. Therefore, in this embodiment, a shortened ID is also set for the master controller 3.
[0049]
In this embodiment, the server 4 as a management device manages the shortened ID, and a table in which the shortened ID is associated with each ID of the remote controller 2 and the master controller 3 is provided in the data / program storage unit 43 of the server 4. . Therefore, the short ID is not set in advance in the remote control device 2 and the master controller 3 like the ID, but is given to the remote control device 2 and the master controller 3 from the server 4 as the management device. The remote controller 2 stores the acquired shortened ID in the storage unit 23, and the master controller 3 stores the acquired shortened ID in the storage unit 33.
[0050]
Hereinafter, a procedure in which the remote controller 2 and the master controller 3 obtain a shortened ID from the server 4 as a management device will be described.
[0051]
There are two types of procedures for the master controller 3 to obtain a shortened ID from the server 4. In the first method, first, the master controller 3 requests the server 4 to transfer a shortened ID. In other words, the master controller 3 is connected to the server 4, the master controller 3 is turned on while the server 4 is turned on, or the operation unit 34 of the master controller 3 sets the shortened ID to the server 4. When the transfer is requested, the shortened ID is transferred from the server 4 to the master controller 3 in the following procedure.
[0052]
As described above, when the master controller 3 notifies the server 4 of the transfer request for the shortened ID, the server 4 starts a program for transferring the shortened ID. Thereafter, the master controller 3 transmits the ID to the server 4. When the server 4 acquires the ID of the master controller 3, the server 4 stores the ID in the data / program storage unit 43, and returns a shortened ID associated with this ID to the master controller 3. Here, the short ID is automatically set by the data processing unit 41 according to a predetermined rule. As this type of rule, it is easiest to use, for example, the order in which transfer requests are made. When the master controller 3 normally receives the shortened ID from the server 4, the master controller 3 notifies the server 4 of normal reception. After the notification is completed, the master controller 3 registers the shortened ID in the storage unit 33, and the server 4 stores the data / program storage unit. 43 stores an ID and an abbreviated ID in association with each other. That is, subsequent communication between the server 4 and the master controller 3 can be performed using the shortened ID.
[0053]
The first method is based on the premise that the server 4 is turned on when the master controller 3 requests the server 4 to transfer the shortened ID, but the master controller 3 requested the transfer of the shortened ID. The server 4 may not be turned on at the time. Therefore, in order to cope with such a case, as a second method, the shortened ID can be transferred to the master controller 3 under the initiative of the server 4. That is, in a state where the power of the master controller 3 is turned on and the server 4 and the master controller 3 are communicably connected, the shortened ID is turned on by turning on the server 4 or operating the operation unit 44 of the server 4. When the notification is issued, the server 4 requests the master controller 3 to notify the ID. When the ID of the master controller 3 is notified to the server 4 in response to this request, the shortened ID is notified to the master controller 3 in the same manner as in the first method, and the shortened ID can be used for subsequent communications. Become.
[0054]
In the second method, since the master controller 3 does not initially hold the ID of the server 4, there is a possibility of data collision when there are a plurality of master controllers 3. Therefore, the ID of each master controller 3 is acquired separately using a known collision avoidance technique. Further, when the server 4 notifies the master controller 3 of the shortened ID, if the master controller 3 fails to receive, the shortened ID is acquired by a known technique such as a retransmission request from the master controller 3. Further, it is desirable that the master controller 3 displays on the display unit 35 that the shortened ID has been normally received. In other words, the light-emitting diode is blinked for a predetermined time or displayed on the liquid crystal display.
[0055]
Next, a method for the remote controller 2 to obtain a shortened ID from the server 4 will be described. When assigning a short ID to the remote controller 2, first, the server 4 selects a short ID to be assigned to the remote controller 2. The shortened ID is automatically generated in the server 4 or set by the user by operating the operation unit 44. When the shortened ID is set by operating the operation unit 44, an appropriate name such as a room name in which the lighting fixture 1a associated with the remote control device 2 is arranged can be used. If entered, an appropriate short ID is associated with the name. When the shortened ID is selected in this way, a message such as “Register new name” is displayed on the display unit 45, so that the target remote controller 2 (identified by the ID of the remote controller 2) The operation unit 44 is operated so as to transfer the shortened ID to the master controller 3 that manages the control. The master controller 3 that has received the short ID of the remote control device 2 temporarily stores the short ID in association with the ID of the remote control device 2. In this state, if the operation unit 24 of the remote control device 2 that is going to receive the shortened ID is operated, the ID of the remote control device 2 is transmitted to the master controller 3, and when the master controller 3 receives the ID of the remote control device 2, it is received. The abbreviated ID corresponding to the ID, the ID of the master controller 3, and the abbreviated ID of the master controller 3 are transmitted to the remote control device 2.
[0056]
The remote controller 2 notifies the master controller 3 that the short ID has been received, and the short ID received from the master controller 3, the ID of the master controller 3 and the short ID are associated with the ID of the remote controller 2 in the storage unit 23. Store. On the other hand, the master controller 3 that has received the notification from the remote control device 2 notifies the server 4 that communication with the remote control device 2 is possible using the short ID, and stores the short ID and ID of the remote control device 2. Stored in the unit 33. The server 4 that has received the notification from the master controller 3 associates the initially input name with the shortened ID and ID of the remote control device 2 and registers them in the data / program storage unit 43. A message such as “Registration of“ name ”completed” is displayed.
[0057]
In general, one luminaire 1a corresponds to one remote control device 2, and data is transmitted between the remote control device 2 and the luminaire 1a by an infrared signal. ID is not required, but if the data transmission medium between the luminaire 1a and the remote control device 2 is a radio wave, the ID is also given to the luminaire 1a and a shortened ID in the same procedure as the remote control device 2. May be registered. Further, since the luminaire 1c transmits data to and from the master controller 3 using radio waves as a transmission medium, the shortened ID is set in the same procedure as the remote control device 2.
[0058]
Further, since it may be necessary to delete or modify the shortened ID set in the component managed by the server 4 as the management apparatus, when deleting the shortened ID, the server 4 shortens it. The same procedure as that for registering the shortened ID may be adopted except that only the point instructing deletion of the ID is changed. Furthermore, registration of the shortened ID may be performed after deletion.
[0059]
As described above, after the shortened ID is set in the master controller 3 and the remote controller 2, data is transmitted between the server 4 and the master controller 3 and between the master controller 3 and the remote controller 2 using the shortened ID. It becomes possible to transmit. As a result, when at least one of the master controller 3 and the remote controller 2 is provided, it is possible to shorten the occupied time of the transmission path compared to the case of using a normal ID.
[0060]
The number of bits of the abbreviated ID described above is defined by the number of components that set the abbreviated ID among the components managed by the server 4. In this embodiment, an abbreviated ID is set so that each component is represented by a bit position, and when the bit value at the bit position corresponding to the component is “1”, the transmission of data to the component is instructed. It shall be. For example, a short ID is not set in the master controller 3, and the remote controller 2 and the lighting fixture 1 c exist as components that transmit data to and from the master controller 3 using radio waves as a transmission medium, and the remote controller 2. If the total number of the lighting fixtures 1c is 16, the short ID is represented by 16 bits, and each component is associated with the bit position of the short ID. In short, the number of bits of the shortened ID is set according to the maximum number of components that are under the management of the server 4 and are to be given the shortened ID.
[0061]
FIG. 9A shows the format of a signal transmitted from the master controller 3 to the remote control device 2 and the lighting fixture 1c when the maximum number of components is 16. As described above, since the low-power communication system requires a 48-bit identification code, in this embodiment, the transmission source ID is used as the identification code, and the transmission destination is a short ID (16 bits). The bit length of the signal to be transmitted can be reduced while satisfying the demand as a power communication system. That is, the signals transmitted from the master controller 3 to the remote control device 2 and the lighting fixture 1c are, as shown in FIG. 9A, the ID (ID1) of the master controller 3, the type of transmission destination (DST), and the transmission destination. Short ID (SID) and data (DAT). Here, although the ID set to the transmission source is 48 bits, the transmission source ID (ID1) shown in FIG. 9A includes the checksum C (see FIG. 8) as described above. The bit length is larger than the bit. The type of transmission destination (DST) has a 4-bit configuration, and the transmission destination indicates four types of the master controller 3, the remote controller 2, the lighting fixture 1c, the remote control 2 and the lighting fixture 1c by bit positions. Is set as follows. In addition, the destination short ID (SID) has a 16-bit configuration. For example, when data (DAT) is to be transmitted to No. 1, No. 3, No. 16, for example, as shown in FIG. The bit values of the 3rd and 16th bit positions are set to “1”, and the bit values of the other bit positions are set to “0”. The data (DAT) can be transmitted in various contents, but the master controller 3 sends data to the remote control device 2 for controlling the lighting state or mode switching for instructing the operating state of the remote control device 2. It becomes the data of.
[0062]
The same applies to the case where a signal is transmitted from the remote control device 2 to the master controller 3. As shown in FIG. 10A, the ID (ID2) of the remote control device 2 as the transmission source and the type of transmission destination (DST). And a destination short ID (SID) and data (DAT). Here, if the maximum number of master controllers 3 that are transmission destinations is four, the transmission destination ID (SID) has a 4-bit configuration. For example, the remote controller 2 sends data ( When transmitting (DAT), as shown in FIG. 10B, the bit value of the bit position of the first bit is set to “1”, and the bit values of other bit positions are set to “0”. .
[0063]
As described above, after setting the shortened ID in the lighting fixture 1c, the remote control device 2, and the master controller 3, it is possible to give an instruction to the remote control device 2 and the lighting fixtures 1a to 1c from the server 4 via the master controller 3. become. Hereinafter, a procedure for transmitting an instruction from the server 4 will be described.
[0064]
First, a case where the master controller 3 transmits data to a plurality of transmission destinations (the lighting fixture 1c and the remote control device 2) will be described. Here, a case where the maximum number of transmission destinations of the master controller 3 is 16 and data is transmitted to the three remote control devices 2 is illustrated. The server 4 inputs the data transmission destination and the instruction contents from the operation unit 44. At this time, the selected content is displayed on the display unit 45, and a message such as “Send“ selected content ”” is displayed. When transmission is instructed by the operation unit 44 in this state, data is transmitted from the server 4 to the master controller 3. The master controller 3 that has received the data notifies all transmission destinations of the start of data transmission by simultaneous broadcast. Here, the signal transmitted from the master controller 3 to the remote controller 2 is in the format shown in FIG. 9A, and the remote controller 2 is selected as the transmission destination (DST), and the short ID (SID) of the transmission destination is selected. ) Is a form in which the bit value of the bit position corresponding to the target remote controller 2 is set to “1”. Therefore, if the three remote control devices 2 are associated with the first bit to the third bit in the destination short ID (SID), as shown in FIG. The bit value is set to “1” at 3 bit positions of 3 bits. That is, the instruction content is notified from the master controller 3 to all the remote control devices 2 to be notified by simultaneous broadcasting. Since the remote control device 2 receives the instruction content as data (DAT), it controls the illumination load 1a according to the instruction content.
[0065]
Next, the master controller 3 individually transmits signals in the form of FIG. 9A to the three remote control devices 2 in order. At this time, the master controller 3 performs a time limit of 2 seconds at maximum for each signal transmission. During this time limit, the master controller 3 is performing carrier sense, and is a time required in the specific low-power radio as a state in which the frequency band is not used by another radio device. First, in the format shown in FIG. 9A, only the bit value of the first bit is set to “1” as shown in FIG. 11B, and the destination short ID (SID) is set. A signal including data (DAT) requesting a timed operation is transmitted from the master controller 3. The master controller 3 starts the timed operation for 2 seconds after sending the signal, and ends the timed operation when the signal of the format shown in FIG. 10A is returned from the remote control device 2 during the timed operation. In the signal returned from the remote control device 2, the destination short ID (SID) is 4 bits as in FIG. 10B, and is a bit at the bit position (for example, the first bit) designating the master controller 3. Only the value is “1”.
[0066]
In the signal transmitted from the master controller 3 to the other remote controller 2, the destination short ID (SID) is in the format shown in FIGS. 11 (c) and 11 (d). That is, a signal having a bit value of “1” for the second bit and a signal having a bit value of “3” for the third bit are sequentially transmitted. Further, the master controller 3 performs a 2 second timed operation every time the signal of the format shown in FIG. 9A is transmitted, and the remote controller 2 returns a signal of the format shown in FIG. 10A during the timed operation. Then, the timed operation is stopped.
[0067]
As described above, all of the remote control devices 2 specified in the destination short ID (SID) included in the signal transmitted from the master controller 3 to the remote control device 2 simultaneously are separately provided. After the signal is transmitted, a signal having the same content as that when the simultaneous broadcast is performed to the remote controller 2 is transmitted from the master controller 3 to the server 4. That is, the signal transmitted from the master controller 3 to the server 4 is a signal in the format shown in FIG. 9A, and the destination short ID (SID) is in the form shown in FIG. The server 4 can know that the instruction content has been transmitted to each remote control device 2 by receiving this signal.
[0068]
When the number of transmission destinations from the master controller 3 is one, the only difference is that processing for changing the transmission destinations in order and transmitting signals is not necessary, but the other processing procedures are the same. That is, when the server 4 notifies the master controller 3 of the ID of the remote control device 2 and the instruction content, it corresponds to the remote control device 2 (or the lighting fixture 1c) that intends to give an instruction in the destination short ID (SID). A signal in which the bit value to be set to “1” is sent from the master controller 3. Thereafter, the master controller 3 transmits the same signal to the remote control device 2 again and performs a timed operation for 2 seconds. When a signal is returned from the remote control device 2 to the master controller 3 during the timed operation, the timed operation is performed. It ends. Further, since the master controller 3 gives only one remote control device 2, when the master controller 3 returns a signal from the remote control device 2 and completes the timed operation, the instruction content to the remote control device 2 is sent to the server 4. Notify that has been transmitted.
[0069]
As described above, since simultaneous broadcast is performed when an instruction is given from a master controller 3 to a plurality of remote control devices 2, a plurality of lighting fixtures 1a can be controlled simultaneously without delay. Moreover, since the master controller 3 waits for a return from the remote control device 2 and notifies the server 4 that the return from the remote control device 2 has been received, it is confirmed whether or not the remote control device 2 has received the instruction content. In addition, since the confirmation operation is performed individually for each remote controller 2 or lighting fixture 1c, collision of signals for confirmation can be avoided and whether or not the instruction content has been received can be confirmed individually. Is possible.
[0070]
By the way, although the example mentioned above is an example in which the instruction content given to the remote controller 2 or the lighting fixture 1c by the master controller 3 is normally received, the instruction content given from the master controller 3 is normally received by the transmission destination. It may not be done. In the above-described operation, the master controller 3 individually designates the remote controller 2 to transmit data, and then performs a 2-second timed operation. When a signal is returned during the timed operation, the instruction content is normally received at the transmission destination. It is considered that it was done. On the other hand, if the signal is not returned during the 2-second timed operation, the instruction content is not normally received by the transmission destination. In this case, the master controller 3 retransmits the data to the transmission destination. . However, when there are a plurality of destinations, even if the instruction contents are not normally received for any one of the destinations while transmitting signals individually to each destination, the instruction contents are not sent to the next destination. The transmission process is continued, and retransmission is performed when the process of transmitting signals to all transmission destinations is completed. At the time of retransmission, the operation when the master controller 3 first receives an instruction from the server 4 is repeated. In other words, after performing simultaneous broadcasting, an operation of transmitting signals individually and waiting for a return is performed. The maximum number of retransmissions is set in advance, or is appropriately set by the user by operating the operation unit 34 of the master controller 3.
[0071]
When an abnormality is detected in transmission of a signal from the master controller 3 to the transmission destination, it is desirable to notify the abnormality by the display unit 35. In addition, a notification unit such as a buzzer may be provided in the master controller 3, and a notification sound may be notified when an abnormality occurs. In addition, since the presence or absence of abnormality is detected individually for each transmission destination, it is also possible to notify the transmission destination in which an abnormality has occurred so that it can be distinguished.
[0072]
When the reception of the instruction content cannot be confirmed even if retransmission is performed as described above, the master controller 3 notifies the server 4 of the transmission destination (remote control device 2 or lighting fixture 1c) that did not normally receive the instruction content, In the server 4, the display unit 45 displays “no response from the remote controller of“ name ”(short ID)”.
[0073]
That is, when the instruction content is transmitted to the three remote control devices 3 and the instruction content is not received by the remote control device 3 whose destination short ID (SID) corresponds to the first bit, FIG. 12, the master controller 3 notifies the server 4 of the bit value of the first bit of the data corresponding to the destination short ID (SID) as “0” (in a normal state, FIG. The bit value of the first bit is “1” as in e)). The above-described operation is performed when there are a plurality of (three in the example) transmission destinations of the master controller 3, but the same processing is performed even when there is one.
[0074]
In the retransmission process when there are a plurality of transmission destinations as described above, data transmission to all the transmission destinations is performed again. Therefore, when it is necessary to perform simultaneous control on a plurality of transmission destinations, for example, When performing time adjustment or switching the operation mode of the transmission destination to the same mode, it is possible to substantially match the operation timing of the transmission destination. Further, since the server 4 or the master controller 3 notifies the transmission destination in which the abnormality has occurred, the transmission destination in which the abnormality has occurred can be easily identified, and the abnormality can be quickly dealt with and maintenance can be performed. It becomes easy.
[0075]
In the above-described example, when the instruction content is transmitted to a plurality of transmission destinations, the instruction content is retransmitted to all transmission destinations even if there is one transmission destination that does not normally receive the instruction content. It may be wasted if the instruction content is retransmitted even to a normally received transmission destination. For example, when the lighting fixtures 1a to 1c or the remote control device 2 include the sensor unit 16 comma 26 and the sensitivity of the sensor unit 16 is changed, it is not necessary to align the operation timing of each transmission destination. Instead, if the process of resending the instruction contents to all the transmission destinations is performed as described above, the time required for the communication process between the master controller 3 and the transmission destination becomes long. Therefore, in such a case, it is desirable to perform retransmission only for a transmission destination that has not received instruction content normally.
[0076]
In other words, the master controller 3 individually transmits data to all the transmission destinations designated as the destination short ID (SID) at the time of simultaneous broadcast, receives a return from each transmission destination, and transmits all transmissions. After the process of individually transmitting data for the destination ends (that is, there is a normal reception response from the last transmission destination, or after the timed operation ends without a normal reception response), the instruction content is received normally A signal including instruction content data (DAT) is individually transmitted to the transmission destination that has not been performed. This data (DAT) is the content transmitted at the time of simultaneous broadcast, but the destination short ID (SID) is not simultaneous broadcast, but the destinations that were not received normally are specified in order and retransmitted. . If the instruction contents cannot be normally received at all the transmission destinations until the maximum number of retransmissions specified by repeating this process is reached, the instruction contents are not normally received from the master controller 3 to the server 4. Notify the destination. In short, the same processing as in the case of resending to all destinations is performed.
[0077]
In addition, when there is a transmission destination that has not received the instruction content normally, whether to retransmit to all transmission destinations or only to the transmission destination in which an abnormality has occurred is determined in the instruction content (data (DAT)). It is possible to distinguish by type, or it is also possible to distinguish by the length of data (DAT). For example, if retransmission is made to all destinations, the time required for communication processing will be longer than if retransmission is made only to destinations where an abnormality has occurred. Therefore, only when data (DAT) is shorter than a specified value It is desirable to select a process to be retransmitted to the destination.
[0078]
The above-described operation relates to the transmission process between the master controller 3 and the lighting fixture 1c or the remote control device 2, but the transmission process between the server 4 and the master controller 3 is performed as follows. desirable. That is, after transmitting a signal from the server 4 to the master controller 3, the server 4 starts a timed operation. This timed operation is the same as the timed operation by the master controller 3, but is set longer than the timed time of the master controller 3. If there is a return from the master controller 3 during the time limit in the server 4, the server 4 determines that normal transmission processing has been performed with the master controller 3.
[0079]
On the other hand, if the return from the master controller 3 cannot be received during the time limit, it is determined that there is an abnormality with the master controller 3, and the display unit 45 notifies the abnormality. When there is an abnormality, it is desirable to retransmit the signal to the master controller 3 after the timed operation is completed. The maximum number of retransmissions is set in advance, or is set by the user operating the operation unit 44. Notification for an abnormality is performed when it is first determined that an abnormality has occurred, or when an abnormality is not resolved even if retransmission is performed. It is also possible to notify abnormality in both cases.
[0080]
Further, it may be distinguished whether or not to perform retransmission according to the instruction content transmitted from the server 4 to the master controller 3. For example, if the user operates the operation unit 44 in the server 4 and the occurrence of an abnormality can be immediately confirmed by the display on the display unit 45 or the like, the user can perform a transmission operation, so that retransmission is automatically performed. There is no need to do it. On the other hand, when the server 4 transmits data to the master controller 3 by operating the terminal 6, or when the server 4 transmits data to the master controller 3 according to an instruction from the remote controller 2 or the lighting fixture 1c, the server 4 It is desirable to automatically retransmit when data is automatically transmitted.
[0081]
The time limit after transmitting data in the server 4 may be a fixed time, but the time limit may be changed according to at least one of the type of transmission destination and the number of transmission destinations. For example, when data is transmitted only to the master controller 3 and when data is transmitted to the remote controller 2, the time required for response is longer when data is transmitted to the remote controller 2. 2 is set to a longer time limit for data transmission. Further, the time required for communication is longer when the number of remote control devices 2 that transmit data is one and ten when the number is ten, and the time until a normal response is obtained is calculated. Therefore, it is desirable to set the time limit of the server 4 based on the calculated time.
[0082]
As described above, an abnormality in communication with the master controller 3 can be detected in the server 4, and data is retransmitted when the abnormality is detected, so that reliability in communication control can be improved. Further, if the time limit from when the data is transmitted from the server 4 to the master controller 3 until the return from the master controller 3 is received is changed according to the destination, the server 4 can continue without waiting for an unnecessarily long time. It becomes possible to shift to processing.
[0083]
In the configuration example described above, the lighting fixtures 1a and 1b employ a configuration that only receives infrared signals, but it is necessary to notify the remote controller 2 and the master controller 3 of the lighting state of the lighting fixtures 1a and 1b. If so, a configuration in which signals are transmitted also from the lighting fixtures 1a and 1b to the remote controller 2 and the master controller 3 may be employed.
[0084]
(Second Embodiment)
In the first embodiment, the server 4 and the master controller 3 are connected separately by wire, but as shown in FIG. 14, the master control server 5 in which the server 4 and the master controller 3 are integrated is provided. It may be used as a management device. The master control server 5 can be realized by using a personal computer. The basic configuration is the same as that of the server 4 and includes a control unit 50 having a microprocessor as a main component, and an ID, an abbreviated ID, and a name. Are stored in association with each other, and a data processing unit 53 storing various programs including a program for setting an abbreviated ID. Further, a communication unit 52 that can be connected to the lighting fixtures 1 b and 1 c, the remote control device 2, and the network NT is connected to the control unit 50. The master control server 5 includes an operation unit 54 including a keyboard, and can perform various settings for the managed lighting fixtures 1a to 1c and the remote control device 2 and transmit desired commands. In addition, a display unit 55 is provided so that the contents of various settings can be displayed and the contents of the trouble can be notified when the trouble occurs. A CRT or a liquid crystal display is used for the display unit 55.
[0085]
If the master control server 5 is used, the system shown in FIG. 1 has the configuration shown in FIG. That is, the master control server 5 is used in place of the server 4 and the master controller 3. In this configuration, the number of system components can be reduced as compared to the first embodiment, and communication between the server 4 and the master controller 3 is not necessary, leading to cost reduction and setting of a shortened ID. And the transmission procedure at the time of erasure is simplified. As a result, the transmission error rate is also reduced. Other configurations and operations are the same as those of the first embodiment.
[0086]
If no operation by the terminal 6 is required, it is possible to use a server 4 that does not have a function of connecting to the external network NT. That is, a configuration in which the server 4 is not connected to the network NT as shown in FIG. 15 and a configuration in which the master control server 5 is not connected to the network NT as shown in FIG. 16 may be adopted. Furthermore, as shown in FIG. 17, the master controller 3 does not have a function of controlling the lighting fixture 1c by radio waves, or the master controller 3 does not pass through the remote control device 2 as shown in FIG. It is also possible to control 1c. In any configuration, since the master controller 3 transmits instruction contents using radio waves to at least one of the remote controller 2 and the lighting fixture 1c, it is shortened separately from the normal ID as in the above-described embodiment. By setting the ID, the transmission time can be shortened.
[0087]
In addition, when the lighting fixtures 1a to 1c or the remote control device 2 are provided with human sensors as described above, the server 4 accumulates information related to human detection to check the usage status of each room in the house. It is useful for crime prevention by notifying the terminal 6 or the like that a person is normally detected during a time period when no person is present, or conversely to the terminal 6 that a person is not normally detected during a time period when a person is present. By notifying, it is possible to confirm the safety of a person. Similarly, in the case where a brightness sensor is provided, when a brightness different from the brightness predicted according to the time zone is detected, the terminal 6 is notified and used for crime prevention and safety confirmation, By accumulating changes in brightness in the server 4, it is possible to make use of the lighting design of each room.
[0088]
Data between the remote control device 2 and the lighting fixture 1a may be transmitted using another transmission medium without depending on the infrared signal. For example, ultrasonic waves, radio waves (other than specific low power radio / specific power saving radio) It is also possible to use a weak radio), a dedicated signal line, a lamp line (by power line carrier technology), and the like. In addition, the transmission path between the remote controller 2 and the master controller 3 uses other weak radio waves in addition to the specific low power radio, or transmission using a dedicated signal line, telephone line, infrared ray, lamp line, etc. as a transmission medium. A path may be formed. In addition to the RS-232C cable, the transmission path connecting the master controller 3 and the server 4 is a USB cable, dedicated signal cable, telephone line, Ethernet cable, radio wave, infrared ray, and power line (depending on the power line carrier technology). Etc. can be used. Further, although the personal computer is exemplified as the server 4, the function of the server 4 can be incorporated in a digital television, set top box, dedicated home server, telephone, facsimile, etc. capable of bidirectional communication. As the network NT connected to the server 4, a public telephone line, WAN, intranet, commercial radio network, satellite communication network, CATV, etc. may be used in addition to the Internet. However, whatever transmission path is used, a part of the transmission path between the server 4 and the lighting fixtures 1a to 1c includes a transmission path using radio waves.
[0089]
【The invention's effect】
  Invention of Claim 1According to the configuration ofSince a radio wave is used as a transmission medium for a part of the transmission path, it becomes possible to control a plurality of lighting fixtures collectively. In addition, since the contents of the instructions can be reached beyond the line of sight, it is possible to control the lighting devices in the house to be turned on all at once, for example, or to turn on and off the lighting devices in the appropriate pattern.The Also, between the management device and the master controllerThe transmission path uses radio waves as the transmission medium,Since infrared rays are used as a transmission medium between the remote control device and the lighting fixture,Off-the-shelf lighting fixtures can be used.Furthermore, instructions are transmitted almost simultaneously to all control targets by simultaneous broadcasting, and the operation can be confirmed individually for each control target. It becomes easy to let you.
[0095]
  According to the configuration of the invention of claim 2,Since the instruction contents are transmitted almost simultaneously to all the objects to be controlled, it becomes easy to correspond to the instruction contents that are required to be controlled almost simultaneously. In particular, even when there is an abnormality in communication, it is possible to transmit the instruction content to all the control objects almost simultaneously.
[0096]
  According to the configuration of the invention of claim 3, the communicationSince the contents of the instruction are retransmitted only to the control target having an abnormality in communication, the time for occupying the transmission path is relatively short, and the responsiveness can be improved.
[0097]
  According to the configuration of the invention of claim 4,It is possible to control as many control objects as possible, and even if any of the lighting fixtures fails, the instruction content can be transmitted to the lighting fixtures that have not failed.
[0098]
  According to the configuration of the invention of claim 5, the communicationSince the communication abnormality is notified, it is easy to cope with the communication abnormality.
[0099]
  According to the structure of the invention of claim 6, the pipeEach in the physical unitRemote control deviceCan manage abnormalities.
[0100]
  According to the configuration of the invention of claim 7, the communicationIt is possible to quickly deal with the abnormality by notifying the abnormality of the communication.
[0101]
  According to the configuration of the invention of claim 8,It is possible to monitor the operating state of the lighting fixtures by a terminal on the network and to give an instruction to the management device from the terminal.
[0102]
  According to the configuration of the invention of claim 9, the transmissionWhile satisfying the requirements of the identification code when using a specific low power radio by the ID of the source, since the shortened ID is used for the destination, the increase in the signal length is relatively small even if there are a plurality of destinations. As a result, response delay can be reduced.The
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of the present invention.
FIG. 2 is a block diagram showing a lighting fixture used in the above.
FIG. 3 is a block diagram showing a remote control device used in the above.
FIG. 4 is a block diagram showing a master controller used in the above.
FIG. 5 is a block diagram showing a server used in the above.
FIG. 6 is an operation explanatory view of the above.
FIG. 7 is an operation explanatory diagram of the above.
FIG. 8 is an operation explanatory view of the above.
FIG. 9 is an operation explanatory view of the above.
FIG. 10 is an operation explanatory diagram of the above.
FIG. 11 is an operation explanatory diagram of the above.
FIG. 12 is an operation explanatory diagram of the above.
FIG. 13 is a block diagram showing a second embodiment of the present invention.
FIG. 14 is a block diagram showing a master control server used in the above.
FIG. 15 is a block diagram showing another configuration example of the present invention.
FIG. 16 is a block diagram showing still another configuration example of the present invention.
FIG. 17 is a block diagram showing another configuration example of the present invention.
FIG. 18 is a block diagram showing still another configuration example of the present invention.
[Explanation of symbols]
1a-1c Lighting equipment
2 Remote control device
3 Master controller
4 servers
5 Master control server
6 terminal
NT network

Claims (9)

A remote control device that remotely controls the lighting state of the lighting fixture and is assigned an identification code; a management device that manages the identification code of the remote control device and instructs the lighting state of the lighting fixture via the remote control device; management device and a transmission path for transmitting a signal including the identification code as a transmission medium radio waves and at least part of the communication path via a remote control device with the luminaire, the remote control device, the management device And a master controller capable of bidirectional communication with the master controller via a transmission line, the remote controller communicating with the luminaire using infrared rays as a transmission medium with the identification code set in association with the luminaire When the master controller designates the identification code of the remote control device associated with the lighting fixture to be controlled at once by simultaneous broadcasting, After sending a signal including the instruction content to control the lighting fixture, a signal designating the individual identification code of the remote control device associated with the lighting fixture to be controlled is transmitted to confirm reception of the instruction content. The remote control device returns a response to the master controller when receiving a signal designating an individual identification code . When the master controller cannot receive a response from the remote control device associated with the lighting fixture to be controlled, the master controller collectively designates the identification code to be controlled and sends a signal including the instruction content, The lighting device according to claim 1, wherein a process of transmitting a signal designating an individual identification code of a remote control device associated with a target lighting device is repeated . When the master controller cannot receive a response from the remote control device associated with the lighting fixture to be controlled, the master controller designates the identification code of the remote control device that could not receive the response and sends a signal including the instruction content The lighting device according to claim 1, wherein a process of transmitting a signal designating an identification code of the remote control device is repeated . A plurality of the remote control devices are provided, and the master controller returns a response from the remote control device within a specified time period after sending a signal designating an individual identification code of the remote control device, or returns a response. 2. The lighting device according to claim 1, wherein a signal designating an identification code of another remote control device is transmitted when a prescribed time limit has expired . 2. The master controller, after sending a signal designating an individual identification code of the remote control device, determines that a communication error has occurred and notifies it when a response from the remote control device is not returned. Lighting equipment. The master controller notifies the remote control device to the management device when a response from the remote control device is not returned after sending a signal designating an individual identification code of the remote control device. The lighting device described . The lighting device according to claim 5, wherein any one of the master controller, the remote control device, the management device, and the lighting fixture includes notification means for notifying communication abnormality . 8. The lighting device according to claim 1, wherein the management device is connected to an external network, and information held by the management device can be transferred to a terminal on the network . The identification code is composed of an ID unique to the remote control device and a shortened ID whose data length is shorter than the ID and which allows the management device to identify the managed remote control device. lighting equipment according to claim 1, wherein the designated at ID, and wherein the specifying the destination in the short ID to.

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