JP3813881B2 - Lighting system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a lighting system, and more particularly to a lighting system that controls a plurality of lighting fixtures using infrared signals.
[0002]
[Prior art]
Various technologies are known as lighting systems that collectively control a plurality of lighting fixtures.
For example, Japanese Patent Laid-Open No. 11-73814 proposes an illumination system that uses a fluorescent lamp fixture with a sensor to interlock the fluorescent lamp fixture. FIG. 12 is a schematic layout diagram of a conventional illumination system disclosed in this publication.
In the figure, reference numeral 10 denotes a passage such as a corridor, and fluorescent lamps 31 to 36 are arranged in a row on the ceiling. Reference numerals 37 and 39 denote illumination controllers A and B installed in the vicinity of the fluorescent lamp fixtures 31 and 36, respectively.
Human sensors A38 and B40 are mounted inside the lighting controllers A37 and B39, respectively.
The human sensors A38 and B40 detect a human body that has entered the detection area, and include, for example, a pyroelectric infrared sensor having a predetermined viewing angle. Reference numeral 41 denotes a signal line connecting the illumination controllers A37 and B39 and the fluorescent lamp fixtures 31 to 36.
[0003]
The two lighting controllers A37 and B39 are installed on the ceiling near the entrance / exit of the passage 10, respectively. Only when a person passes through the passage 10, the fluorescent lamp fixtures 31 to 36 are turned on. When no person is present in the passage 10, the fluorescent lamp fixtures 31 to 36 are turned off or dimmed (dimmed) to realize energy saving. To do.
[0004]
FIG. 13 is a schematic diagram showing an operation of the illumination system shown in FIG. 12 viewed from the horizontal direction.
Components identical or corresponding to those in FIG.
In FIG. 13, 17 is a ceiling surface, 18 is a floor surface, and 19 and 20 are detection areas by human sensors A38 and B40, respectively. The detection areas 19 and 20 extend to the floor 18 in a conical shape with the human sensors A38 and B40 as apexes, respectively. Reference numeral 21 denotes a person who passes through the detection area 19 and moves in the direction of the fluorescent lamp fixture 36 from below the fluorescent lamp fixture 31 in the passage 10.
[0005]
FIG. 14 is a circuit block diagram of the illumination system shown in FIG. In order to illustrate only the signal flow, part of the fluorescent lamp fixture and power wiring are omitted.
In the figure, reference numerals 42 and 43 denote timers which are started by detection signals from the human sensors A38 and B40, respectively. Signals corresponding to ON / OFF of the timers 42 and 43 (hereinafter referred to as operation signals) are both transmitted via the signal line 41. Sent.
[0006]
The operation of the lighting system when the human sensor A38 detects the person 21 will be described with reference to FIGS.
The timer 42 is operated by the detection signal of the human sensor A 38, and an ON operation signal is transmitted from the timer 42 to the fluorescent lamp fixtures 31 to 36 via the signal line 41.
At the same time, counting for a preset time of about 1 to 5 minutes starts.
The fluorescent lamp fixture 31 includes a control circuit 44, an inverter 45, the fluorescent lamp 2, and the like, and a signal line 41 is connected to the control circuit 44. The control circuit 44 is set to oscillate the inverter 45 when an ON operation signal is transmitted from either one of the timers 42 and 43.
[0007]
Therefore, the inverter 45 oscillates in response to the ON operation signal from the timer 42, and the high-frequency power is supplied to the fluorescent lamp 2 of the fluorescent lamp fixture 31 by this oscillation to light up. This operation is the same for the fluorescent lamp fixtures 32 to 36, and as a result, all the fluorescent lamps 2 are turned on. When the counting of the timer 42 is completed (time up), the operation signal from the timer 42 is turned off, and the fluorescent lamp 2 in the fluorescent lamp fixtures 31 to 36 is turned off or dimmed.
This series of operations is the same when the human sensor 40 detects the person 21.
[0008]
[Problems to be solved by the invention]
However, in the conventional lighting system shown in FIGS. 12 to 14, the plurality of fluorescent lamp fixtures 31 to 36 are controlled by the lighting controller A37 or B39. Therefore, the lighting controller A37 or B39 and the fluorescent lamp fixtures 31 to 36 are controlled. Need to be connected with the signal line 41, and there is a problem that the construction is costly and it takes time to change the existing fluorescent lamp fixture.
In addition, when the fluorescent lamp fixtures are configured to be linked using infrared signals, when a plurality of fluorescent lamp fixtures simultaneously receive infrared signals, infrared signals are transmitted from all the received fluorescent lamp fixtures, and infrared signal collisions occur. Therefore, there is a problem that the control signal cannot be transmitted.
[0009]
The present invention has been made to solve such problems, and an object of the present invention is to provide an illumination system that eliminates the need for wiring signal lines to each luminaire and can prevent collision of infrared rays.
[0010]
[Means for Solving the Problems]
An illumination system according to the present invention includes an infrared receiving unit and a transmitting unit, and in the illumination system configured by adjacently arranging a plurality of lighting fixtures that transmit and receive control signals via the infrared rays, the plurality of lighting fixtures includes: A transmission number indicating a transmission order is assigned in advance, and the lighting fixture A is divided into a lighting fixture A having a control starting means and a lighting fixture B not having a control starting means. The lighting fixture A has an output from the control starting means. Then, dimming control is started, and first and second signals are generated from the dimming degree information, its own transmission number, and first and second different transmission order information, respectively, and these two signals are used as control signals. output to its transmission means, to calculate the transmission time period to be transmitted to other luminaires a or the luminaire B based on the transmission number and the transmission order information in the control signal received as its transmission number of luminaire When the control signal transmitted from the lighting fixture A or another lighting fixture B is received, the transmission number in the received control signal is replaced with its own transmission number as a new control signal to its own transmission means. Output, calculate the transmission time zone until sending a new control signal from its own transmission number and the transmission number and transmission order information in the received control signal, and send and receive based on this transmission time zone The dimming control is configured based on the dimming degree information in the control signal.
[0011]
Further , the first and second transmission order information are configured to be order information in which the transmission order increases and order information in which the transmission number decreases, respectively.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
FIG. 1 is a schematic view showing a configuration of an illumination system showing an embodiment of the present invention, as seen from below.
This embodiment is installed in a place where people are not resident such as passages, and when there are no people, the fluorescent lamp of the fluorescent lamp fixture that is a lighting fixture is dimmed or dimmed to reduce power consumption, Realizes energy saving.
The same or corresponding parts as those in the conventional example are denoted by the same reference numerals and description thereof is omitted.
[0013]
In FIG. 1, reference numerals 11 and 16 denote fluorescent lamp fixtures A that are installed in the vicinity of the entrance / exit of the passage 10 and are provided with a human sensor 7 as a control start means. Reference numerals 12 to 15 denote fluorescent lamp fixtures B that are installed between the exit and the entrance and do not include the human sensor 7. Reference numerals 5 and 6 denote an infrared receiver and an infrared transmitter, respectively.
Thus, in this embodiment, there are two types of fluorescent lamp fixtures, and the difference is in the presence or absence of the human sensor 7.
2 and 3 are plan views of the fluorescent lamp apparatus A and the fluorescent lamp apparatus B, respectively.
[0014]
In FIG. 2, 1 is a fluorescent lamp fixture body (hereinafter referred to as a fluorescent lamp fixture), 3 is a reflector attached to the fluorescent fixture 1, and 4 a is a lighting device, which is attached inside the reflector 3. The reflector 3 is provided with an opening through which the infrared receiver 5 and the infrared transmitter 6 attached to the lighting device 4 a protrude from the reflector 3. The human sensor 7 is mounted on the lighting device 4 a in the same manner as the infrared receiver 5 and the infrared transmitter 6.
3 is almost identical to FIG. 2 except that the human sensor 7 is not mounted. In the figure, 4b is a lighting device.
[0015]
FIG. 4 is a circuit block diagram of the fluorescent lamp fixture A.
In the figure, reference numeral 8a denotes a control unit incorporating a timer 80 that operates based on the detection signal of the human sensor 7.
The control unit 8a includes an infrared receiver 5 that receives infrared light pulse-modulated with a carrier wave (38 kHz) and converts the infrared signal into an electric signal, an infrared transmitter 6 that converts the electric signal into infrared light pulse-modulated with a carrier wave, The sensation sensor 7 and the inverter 9 are connected. The infrared signal received by the infrared receiver 5 is decoded and sent to the inverter 9 as a dimming signal, the fluorescent lamp 2 is dimmed by the inverter 9 and a part of the infrared signal received by the infrared receiver 5 is changed. And output to the infrared transmitter 6 as an infrared signal for relay.
[0016]
FIG. 5 is a circuit block diagram of the fluorescent lamp fixture B.
In the figure, 8b is a control unit. The control unit 8 b is connected to the infrared receiver 5, the infrared transmitter 6, and the inverter 9. The infrared signal received by the infrared receiver 5 is decoded, sent to the inverter 9 as a dimming signal, a part of the infrared signal received by the infrared receiver 5 is changed, and the infrared signal is transmitted to the infrared transmitter 6 as a relay infrared signal. Output.
A control signal such as a dimming signal between fluorescent lamp fixtures is obtained by further secondary-modulating the aforementioned pulse-modulated carrier wave with a data code.
[0017]
FIG. 6 is a schematic diagram showing the operation of the illumination system according to the present invention as seen from the horizontal direction.
In the drawing, fluorescent lamp fixtures A11 and A16 are respectively installed at the exit and entrance (or entrance and exit) of the passage 10, and a person 21 passing through the passage 10 enters from the fluorescent lamp fixture A11 side.
Reference numerals 22 to 27 denote infrared signals that are reflected by the floor surface 18 and sequentially transmitted to adjacent fluorescent lamp fixtures along the approach direction. More specifically, the infrared signal 22 is sent from the fluorescent lamp fixtures 11 to 12, the infrared signal 23 is sent from the fluorescent lamp fixtures 12 to 13, the infrared signal 24 is sent from the fluorescent lamp fixtures 13 to 14, and the infrared signal 25 is sent from the fluorescent lamp fixtures 14 to 15. The infrared signal 26 is transmitted from the fluorescent lamp fixtures 15 to 16, and the infrared signal 27 is transmitted from the fluorescent lamp fixture 16 to the adjacent fluorescent lamp fixtures.
Although not shown, the dimming degree of the fluorescent lamp is set to switch from 5% to 100% before and after detecting the person 21.
[0018]
FIG. 7 shows the structure of an infrared signal.
In the figure, (1) is the infrared signal of one frame, (2) is the configuration of the infrared signal in the frame, (3) is the configuration of the data part, (4) and (5) are the pulse-modulated infrared signal and the final, respectively. Infrared signal.
[0019]
As shown in (2), one frame of the infrared signal is composed of a data portion, a reader portion for distinguishing the beginning and end of the data portion, and a trailer portion.
In addition, as shown in (3), the data part is an infrared signal ID (specific signal of a device or device that uses infrared rays such as a manufacturer or model), a dimming degree, and an infrared signal assigned to each fluorescent lamp fixture as shown in (3). Are composed of a transmission number indicating the transmission order, a transmission order for selecting two transmission orders, and a parity code used for error detection.
[0020]
Furthermore, since the infrared signal is pulse-modulated as described above, the pulse train is as shown in (4). For example, the reader unit is composed of “1” for 8T time and “0” for 4T time. Here, T represents the basic pulse width, and is set to 0.4 ms, for example. Similarly, in signal 0, T time “1” and T time “0”, in signal 1 T time “1” and 3T time “0”, the trailer portion is T time “1” (referred to as stop bit). Each) is composed of 10T time “0” s. (5) shows the final infrared signal. In the period “1” shown in (4), infrared light pulse-modulated at 38 kHz is output, and no infrared light is output in the period “0”.
[0021]
In addition, transmission number information prescribes | regulates a transmission order so that the infrared rays transmitted from each of fluorescent lamp fixtures A11 and 16 and fluorescent lamp fixtures B12-15 may not collide. Also, the transmission order is ascending order, such as 2 after 2, 1 next, 3 next, 3 then 4, and 6 followed by 5, 5 followed by 4, 4 followed by 3, followed by descending order such as 3. There are two types, and the transmission order information defines ascending order or descending order.
Thus, dimming degree information, transmission number information, transmission order information, and the like are incorporated in the data portion of the infrared signal.
[0022]
Moreover, FIG. 8 shows the structure of the time which each fluorescent lamp fixture transmits.
The transmission time zone is divided into t hours, and further divided into an ascending transmission time zone and a descending transmission time zone.
Each fluorescent lamp fixture transmits a transmission time period from when a signal is received until it transmits the signal, with a time t as a unit, a transmission number in the received infrared signal, its own transmission number, and transmission. Calculate from order information.
[0023]
That is, the transmission time zone is calculated by the following equation for each of descending order and ascending order using t.
In descending order:
Transmission time zone = (transmission number in received control signal−own transmission number) × t
In ascending order:
Transmission time zone = (own transmission number−transmission number in received control signal) × t
[0024]
FIG. 9 is a timing diagram showing transmission of an infrared signal when a person 21 passing through the passage 10 enters from the direction of the fluorescent lamp fixture A11.
In the figure, a rectangular block represents one frame of an infrared signal, and the horizontal axis represents the transmission time assigned to each transmission number by t time intervals.
[0025]
As described above, the time t is divided into the ascending transmission time zone S1 and the descending transmission time zone S2. Each fluorescent lamp fixture is assigned a transmission number. The fluorescent lamp fixture 11 has a transmission number = 1, the fluorescent lamp fixture 12 has a transmission number = 2, the fluorescent lamp fixture 13 has a transmission number = 3, and the fluorescent lamp fixture. 14 is assigned transmission number = 4, fluorescent lamp fixture 15 is assigned transmission number = 5, and fluorescent lamp fixture 16 is assigned transmission number = 6.
The black blocks 50, 51 and 55 each indicate an infrared signal (electrical signal) transmitted for one frame, and the gray blocks 52 and 53 respectively indicate received infrared signals (electrical signals).
[0026]
Also, the black arrows 22 to 27 are the same as the infrared signals shown in FIG. 6, and the white arrow 54 is an infrared that transmits the infrared signal 52 received by the control unit 8a or 8b in each fluorescent lamp fixture. An internal signal when converted into a signal 55 is shown. At this time, the transmission number is replaced with the transmission number of the infrared signal assigned to its own fluorescent lamp fixture, and an infrared signal of one frame is assembled.
[0027]
The operation of the lighting system when a person 21 passing through the passage 10 enters from the fluorescent lamp apparatus A11 side will be described with reference to FIGS.
When the human sensor 7 mounted on the fluorescent lamp fixture A11 detects the person 21, the timer 80 in the control unit 8a is operated, and at the same time, the dimming degree which is information in the data part shown in FIG. = Increase order, transmission number = 1, infrared signal 50, dimming degree = 100%, transmission order = descending order, transmission number = 1, infrared signal 51 is generated.
[0028]
The generated infrared signals 50 and 51 are transmitted in the time periods S1 and S2 of transmission time = 1t, respectively. The transmitted infrared rays 22 are reflected by the floor 18 and reach the fluorescent lamp fixture B12 adjacent to the fluorescent lamp fixture A11. The fluorescent lamp fixture B12 receives the infrared rays 22 from the fluorescent lamp fixture A11 and takes them into the control unit 8b as infrared signals 52 and 53.
[0029]
Since the dimming degree in the infrared signals 52 and 53 is 100%, a dimming degree = 100% command is sent to the inverter 9. From the transmission number = 1 of the received infrared signal 52 and the transmission order = ascending order, it is determined that the infrared signal can be output in the next transmission time zone 2t received from the transmission number 2 of the fluorescent lamp fixture 12 itself. The transmission infrared signal 55 is generated by changing the transmission number of the received infrared signal 52 to 2 (transmission number assigned to the fluorescent lamp fixture B12). Then, the infrared transmitter 6 transmits the infrared ray 23 at S1 in 2t, that is, in an ascending order transmission time zone.
On the other hand, since the other received infrared signal 53 is in the transmission order = descending order, there is no time zone for transmission, and the control unit 8b does not perform processing for infrared transmission.
[0030]
The infrared signal 23 from the fluorescent lamp fixture B12 is received by the adjacent fluorescent lamp fixture B13, and the infrared signal 24 is transmitted immediately after reception through a similar operation. In this way, infrared signals are transmitted in sequence, the signal generated by the fluorescent lamp fixture A11 reaches the fluorescent lamp fixture A16, and the fluorescent lamp fixtures A11 and 16 and the fluorescent lamp fixtures B12 to 15 are turned on at a dimming degree of 100%. Will do.
Thereafter, when the timer 80 in the control unit 8a in the fluorescent lamp fixture 11 times out, the dimming degree information in the data part of the infrared signal shown in FIG. 7 is set to 5%, and two infrared signals in ascending order and descending order are obtained by the same operation. And output as an infrared signal 22. This information is successively transmitted to the fluorescent lamp fixture A11, the fluorescent lamp fixtures B12-15, and the fluorescent lamp fixture A16 as described with reference to FIG. 9, and the fluorescent lamps 2 of the fluorescent lamp fixtures A11, 16 and fluorescent lamp fixtures B12-15 are used. All are dimmed at 5%.
[0031]
Next, the operation of the illumination system when the flow of the infrared signal is in the reverse direction, that is, when a person passing through the passage 10 enters from the fluorescent lamp fixture A16 side will be described.
First, FIG. 10 is a schematic diagram showing the operation of the present illumination system when a person 21 is present in the detection area 20.
FIG. 11 is a time chart showing the transmission of the infrared signal when the flow of the infrared signal is reversed. In the figure, black blocks 56, 57 and 60 indicate a transmission signal (electric signal) of one frame, and gray blocks 58 and 59 indicate a received infrared signal (electric signal). The black arrow represents an infrared signal, and the white arrow 60 represents the control unit 8a of the fluorescent lamp device A or the control unit 8b of the fluorescent lamp device B when the received infrared signal 58 or 59 is converted into the transmitted infrared signal 61. Represents an internal signal.
[0032]
Details of the operation will be described with reference to FIGS.
When the human sensor 7 mounted on the fluorescent lamp fixture A16 detects a person, the human sensor 7 operates the timer 80 in the control unit 8a, and the dimming degree which is information in the data unit shown in FIG. = Increase order, transmission number = 6 , infrared signal 56, dimming degree = 100%, transmission order = descending order, transmission signal = 6 , infrared signal 57 is generated. The generated infrared signals 56 and 57 are transmitted in the time zones S1 and S2 where transmission time = 1t, respectively.
[0033]
The transmitted infrared signal 27 is reflected by the floor surface 18 and reaches the fluorescent lamp fixture B15 adjacent to the fluorescent lamp fixture A16. The fluorescent lamp fixture B15 receives the infrared rays 27 from the fluorescent lamp fixture A16, and takes them into the control unit 8b as infrared signals 58 and 59. Since the dimming degree in the infrared signals 58 and 59 is 100%, a dimming degree = 100% command is sent to the inverter 9. From the transmission number = 16 of the received infrared signal 59 and the transmission order = descending order, it is determined that infrared light can be output in the next transmission time zone 2t received from the transmission number 5 of the fluorescent lamp fixture 15 itself, The transmission infrared signal 60 is generated by changing the transmission number of the reception infrared signal 59 to the transmitter 6 = 5 (transmission number assigned to the fluorescent lamp fixture B15). Then, the infrared transmitter 6 transmits the infrared ray 26 at S2 in 2t, that is, in descending order transmission time zone. Since the other received infrared signal 58 is in the transmission order = ascending order, there is no time zone for transmission, and the control unit 8b does not perform processing for infrared transmission.
[0034]
The infrared rays 26 from the fluorescent lamp fixture B15 are further received by the fluorescent lamp fixture B14 installed adjacent thereto, and similarly, the infrared rays 25 are transmitted immediately after reception. In this way, infrared rays are transmitted in sequence, the signal generated by the fluorescent lamp fixture A16 reaches the fluorescent lamp fixture A11, and the fluorescent lamp fixtures A11 and 16 and the fluorescent lamp fixtures B12 to 15 are turned on at a dimming degree of 100%. become. Thereafter, when the timer 80 of the control unit 8a in the fluorescent lamp fixture 16 expires, the dimming degree, which is information in the data part of the infrared signal shown in FIG. 7, is set to 5%, and the two infrared signals in ascending order and descending order as described above. And output as infrared rays 27. This information is successively transmitted to the fluorescent lamp fixture A16, the fluorescent lamp fixtures B12-15, and the fluorescent lamp fixture A11 as described in FIG. 9, and the fluorescent lamp 2 and the fluorescent lamp fixtures B12-15 of the fluorescent lamp fixtures A11, 16 are transmitted. All of the fluorescent lamps 2 are dimmed at 5%.
[0035]
Thus, in the illumination system of the present invention, the fluorescent lamp fixture A11 is installed in the vicinity of one of the entrances such as the passage, and the infrared transmitter 6 and the infrared receiver are provided in the fluorescent lamp fixtures A11, 16 and the fluorescent lamp fixtures B12-15. When the human sensor 7 is output to the fluorescent lamp fixture A11, an infrared signal is transmitted, and the fluorescent lamp fixtures B12 to B15 and the fluorescent lamp fixture A16 sequentially receive the infrared rays and relay them. A signal is transmitted and the lamp 2 is sequentially turned on with a constant brightness.
[0036]
On the other hand, it is installed in the vicinity of the other doorway, and when the human sensor 7 outputs the fluorescent lamp fixture A16, it transmits an infrared signal, and the fluorescent lamp fixtures B14 to B12 and the fluorescent lamp fixture A11 sequentially receive the infrared signal. Then, the infrared signal is relayed and the lamp 2 is sequentially turned on with a constant brightness.
[0037]
In addition, in the lighting system of the present invention, when there are a plurality of entrances such as a passage, a fluorescent lamp fixture A is installed at each entrance, and the infrared signal is the last signal regardless of which entrance sensor detects a human body. Since multiple transmission orders are set so that the time to transmit to the fluorescent lamp fixture is the shortest, for example, there is a delay in one direction for transmitting infrared signals compared to those that do not set multiple infrared signal transmission orders. Even when the number of fluorescent lamp fixtures is large due to a long passage or the like, it is possible to shorten the time for which infrared rays are transmitted to the last fluorescent fixture. This is because the fluorescent lamp fixture A mounted with the human sensor has the same effect of shortening the time at the center where the installation position is not at the end of the passage, and when an infrared signal from another fluorescent fixture A is received, The operation is similar to that of the lighting fixture B, and infrared rays are relayed.
[0038]
In this embodiment, the fluorescent lamp is controlled to have a dimming degree of 100% when the presence of a person is detected in the passage, and to a dimming degree of 5% at other times, but it may be turned off when there is no person. The light may be dimmed when there are people. Moreover, although the case where the lighting system of the invention is installed in the passage has been described, the same effect can be expected when there is only one entrance such as a locker room or there are three or more entrances in the passage.
Furthermore, even when an illuminance sensor is mounted instead of the human sensor and the illuminance control is performed, the same effect can be obtained without changing the dimming degree. The same effect can be expected by using a switch or a temperature sensor instead of the human sensor.
[0039]
【The invention's effect】
Since the illumination system of the present invention is configured as described above, the following effects can be obtained.
[0040]
A fluorescent lamp fixture A11 is installed near one of the entrances and exits such as a passage, the fluorescent lamp fixtures A11, 16 and fluorescent lamp fixtures B12-15 are provided with the infrared transmitter 6 and the infrared receiver 5, and the fluorescent lamp fixture A11 has a human feeling. When there is an output from the sensor 7, an infrared signal is transmitted, and the fluorescent lamp fixtures B12 to B15 and the fluorescent lamp fixture A16 sequentially receive the infrared rays and relay them to transmit the infrared signal, and the lamp 2 has a certain brightness. Since the lighting, dimming, or extinguishing is sequentially performed, the signal line wiring work to each lighting fixture can be made unnecessary, and the collision of infrared rays can be prevented.
[0041]
Moreover, since the transmission order information is set corresponding to the order information in which the transmission number increases and the order information in which the transmission number decreases, the infrared signal can be transmitted smoothly and quickly.
[Brief description of the drawings]
FIG. 1 is a schematic layout diagram of an illumination system according to Embodiment 1 of the present invention.
FIG. 2 is a plan view of a fluorescent lamp fixture A constituting the illumination system according to Embodiment 1 of the present invention.
FIG. 3 is a plan view of a fluorescent lamp fixture B constituting the illumination system according to Embodiment 1 of the present invention.
FIG. 4 is a block diagram of a fluorescent lamp fixture A constituting the illumination system according to Embodiment 1 of the present invention.
FIG. 5 is a block diagram of a fluorescent lamp fixture B constituting the illumination system according to Embodiment 1 of the present invention.
FIG. 6 is a schematic diagram showing the operation of the illumination system according to Embodiment 1 of the present invention.
FIG. 7 is a configuration diagram of an infrared signal in the illumination system according to Embodiment 1 of the present invention.
FIG. 8 is an explanatory diagram showing an infrared transmission time zone in the illumination system according to Embodiment 1 of the present invention.
FIG. 9 is an infrared signal transmission timing diagram in the illumination system according to Embodiment 1 of the present invention;
FIG. 10 is a schematic diagram showing the operation of the illumination system according to Embodiment 1 of the present invention.
FIG. 11 is an infrared signal transmission timing chart in the illumination system according to Embodiment 1 of the present invention.
FIG. 12 is a schematic layout diagram of a conventional lighting system.
FIG. 13 is a schematic diagram showing the operation of a conventional lighting system.
FIG. 14 is a block diagram showing a circuit configuration of a conventional lighting system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Fluorescent lamp fixture 2 Fluorescent lamp 4a, 4b Lighting device 5 Infrared receiver 6 Infrared transmitter 7 Human sensor 8a, 8b Control part 9 Inverter 10 Passage 11-16 Fluorescent lamp fixture 19,20 Detection area 21 Person 22-27 Infrared 80 timer

Claims (2)

In an illumination system that includes infrared receiving means and transmitting means, and is configured by arranging a plurality of lighting fixtures that perform transmission and reception of control signals via this infrared ray,
The plurality of lighting fixtures are preliminarily assigned with a transmission number indicating a transmission order, and are divided into a lighting fixture A having a control start unit and a lighting fixture B having no control start unit,
When there is an output from the control starting means, the luminaire A starts dimming control, and first, second from the dimming degree information, its own transmission number, and first and second different transmission order information, respectively. , And outputs these two signals as control signals to its own transmission means. Based on its own transmission number, the transmission number in the received control signal, and the transmission order information , the other luminaire A or the illumination Calculate the transmission time zone to be sent to the device B,
When the luminaire B receives a control signal transmitted from the luminaire A or another luminaire B, a new control signal is obtained by replacing the transmission number in the received control signal with its own transmission number. Output to its own transmission means, calculate the transmission time zone until sending a new control signal from its own transmission number, the transmission number in the received control signal and the transmission order information, and send based on this transmission time zone And a lighting system configured to perform dimming control based on dimming degree information in the received control signal.   The lighting system according to claim 1, wherein the first and second transmission order information are order information in which the transmission number increases and order information in which the transmission number decreases, respectively.

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