JP2013235692A - Lighting device, lighting system and dimming method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent reduction in the number of lighting systems that can be connected to one dimmer.SOLUTION: A lighting device according to an embodiment comprises a plurality of lighting control parts provided correspondingly to a plurality of light sources and controlling the lighting of each light source. The lighting device also comprises a distribution part to which a dimming signal including dimming information relating to the dimming of the light sources is input, and which duplicates the dimming signal to generate duplicated dimming signals of the same number as the number of the lighting control parts and amplifies each of the duplicated dimming signals, which have been generated, to distribute to the lighting control parts.

Description

  Embodiments described herein relate generally to a lighting device, a lighting device, and a dimming method.

  Conventionally, when adjusting the light quantity of a light source such as an LED (Light Emitting Diode), PWM dimming using a PWM (Pulse Width Modulation) type dimming signal may be performed. . In PWM dimming, when an operator operates the dimmer, a dimming signal having a duty ratio corresponding to a desired light amount is output, and this dimming signal is input to an illumination device including a light source. In the lighting device, the light source is turned on and off at high speed according to the duty ratio of the dimming signal, and as a result, the light amount of the light source is adjusted. Specifically, for example, when the pulse width of the dimming signal is increased and the period during which the signal level is high is relatively long, the light-off time of the light source is relatively long and the amount of light is reduced.

  As described above, in a lighting device capable of adjusting the amount of light, lighting of the light source is controlled according to a dimming signal input from the dimmer, and a desired brightness can be obtained by adjusting the amount of light. ing. For this reason, lighting devices are generally provided with a lighting circuit for controlling lighting of the light source.

JP-A-1-74066 JP 2011-165400 A

  Incidentally, a plurality of light sources may be mounted on the above-described lighting device. That is, for example, three lighting LEDs of RGB (Red Green Blue) may be mounted on each lighting device, or a plurality of LEDs of the same color may be mounted. And since a capacity | capacitance of an output will increase when a several light source is mounted in an illuminating device, the some lighting circuit corresponding to each light source may be provided.

  A configuration example of such a lighting device is shown in FIG. As shown in FIG. 5, the lighting device connected to the AC power supply 10 is provided with a rectifier circuit 20 and a plurality of lighting circuits 30 a to 30 c. The light sources 40a to 40c are connected to the lighting circuits 30a to 30c, respectively. In this illuminating device, the rectifier circuit 20 rectifies AC power from the AC power supply 10 and supplies it to the lighting circuits 30a to 30c. The lighting circuits 30a to 30c use the current supplied from the rectifier circuit 20 to control the lighting of the light sources 40a to 40c according to a dimming signal input from a dimmer (not shown).

  As described above, when dimming a lighting device including a plurality of lighting circuits, a dimming signal is input to each of the plurality of lighting circuits. As a result, the current flowing through the dimming signal line connecting the dimmer and the lighting device increases as the number of lighting circuits provided in the lighting device increases. That is, for example, when the current value of the dimming signal input to one lighting circuit is 4 mA (milliampere), the dimming signal line connected to the lighting device of FIG. Will flow.

  However, the maximum current value that can be supplied by the dimmer is fixed, and there is an upper limit to the number of lighting circuits that can be connected to one dimmer. For this reason, when many lighting circuits are provided in one lighting device, the current value of the dimming signal required per lighting device increases, and the lighting device that can be connected to one dimmer The number will be limited. Therefore, for example, when a lighting device having one light source is replaced with a lighting device having a plurality of light sources, the number of lighting devices that can be connected to an existing dimmer is reduced. It may be necessary to add more.

  This invention is made | formed in view of this point, and it aims at providing the lighting device, the illuminating device, and the light control method which can prevent the reduction | decrease in the number of the illuminating devices which can be connected to one dimmer. And

  The lighting device according to the embodiment includes a plurality of lighting control units that are provided corresponding to a plurality of light sources and that control lighting of the light sources by electric power supplied from a power source. Further, the lighting device receives an input of a dimming signal including dimming information related to dimming of the plurality of light sources, duplicates the dimming signal, and has the same number of replica dimming as the number of the plurality of lighting control units. A distribution unit is provided that generates a signal, amplifies each of the generated duplicate dimming signals, and distributes the signals to the plurality of lighting control units.

  According to the present invention, it can be expected to prevent a decrease in the number of lighting devices that can be connected to one dimmer.

FIG. 1 is a diagram illustrating a configuration of a lighting device according to the first embodiment. FIG. 2 is a diagram illustrating a configuration of the dimming signal distribution unit according to the first embodiment. FIG. 3 is a diagram illustrating a configuration of the dimming signal receiving unit according to the first embodiment. FIG. 4 is a flowchart showing the operation of the lighting device according to the first embodiment. FIG. 5 is a diagram illustrating a configuration of a dimming signal distribution unit according to the second embodiment. FIG. 6 is a diagram illustrating a configuration of an illumination device including a plurality of light sources.

  Hereinafter, a lighting device, a lighting device, and a dimming method according to an embodiment will be described with reference to the drawings.

  In the lighting device 120 according to each embodiment described below, the lighting circuits 140a to 140c are provided corresponding to the plurality of light sources 150a to 150c, and control lighting of the light sources 150a to 150c, respectively. The dimming signal distribution unit 130 receives a dimming signal including dimming information related to dimming of the plurality of light sources 150a to 150c, and duplicates the dimming signal to determine the number of lighting circuits 140a to 140c. The same number of duplicate dimming signals are generated, and each of the generated duplicate dimming signals is amplified and distributed to a plurality of lighting circuits 140a to 140c.

  In the lighting device 120, the dimming signal distribution unit 130 includes transformers 203a to 203c each including a primary coil to which a dimming signal is input and a plurality of lighting circuits 140a to 140c and the same number of secondary coils. And a duplicate dimming signal is generated in each secondary coil.

  In the lighting device 120 described above, the dimming signal distribution unit 130 includes a microcomputer 503 that generates a duplicate dimming signal based on dimming information included in the dimming signal.

  Further, in the lighting device 120 described above, the dimming signal distribution unit 130 decomposes the dimming information included in the dimming signal into dimming information for each of the plurality of light sources 150a to 150c, and for each of the obtained light sources 150a to 150c. A duplicate dimming signal including the dimming information is generated.

  Further, in the lighting device 120 described above, the dimming signal distribution unit 130 amplifies and distributes the voltage of the generated duplicate dimming signal to a voltage substantially equal to the voltage of the dimming signal.

  Moreover, the illuminating device according to each embodiment includes a plurality of light sources 150a to 150c and the lighting device 120 described above.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration of a lighting device according to the first embodiment. The illuminating device illustrated in FIG. 1 includes an AC power supply 110, a lighting device 120, and light sources 150a to 150c.

  The AC power supply 110 is a power supply having a voltage in the range of 100 to 240 liters (volts), for example, and supplies AC power to the lighting device 120.

  The lighting device 120 uses the AC power supplied from the AC power supply 110 to control lighting of the light sources 150a to 150c including light emitting elements such as LEDs in accordance with a dimming signal input from a dimmer (not shown). To do. At this time, the lighting device 120 receives an input of a dimming signal having the same current value (for example, 4 mA) as in the case of one light source, and controls lighting of the three light sources 150a to 150c by the dimming signal. Specifically, the lighting device 120 includes a dimming signal distribution unit 130 and lighting circuits 140a to 140c corresponding to the light sources 150a to 150c.

  The dimming signal distribution unit 130 duplicates the dimming signal input from a dimmer (not shown), and distributes the obtained duplicate dimming signal to the three lighting circuits 140a to 140c. At this time, the dimming signal input to the dimming signal distribution unit 130 is, for example, a PWM dimming signal and includes dimming information for dimming the light sources 150a to 150c according to the duty ratio. In addition, the current value of the dimming signal input to the dimming signal distribution unit 130 is equal to the current value (for example, 4 mA) of the dimming signal input to the lighting device including one lighting circuit and one light source.

  The dimming signal distribution unit 130 not only distributes the input dimming signal but also amplifies duplicate dimming signals obtained by the number of lighting circuits, and outputs the amplified signals to the lighting circuits 140a to 140c. . At this time, the dimming signal distribution unit 130 amplifies the duplicate dimming signal to a voltage substantially the same as the voltage of the input dimming signal. As a result, even if the dimming signal input to the dimming signal distribution unit 130 has the same current value as the dimming signal input to the lighting device including only one light source, the dimming signal is input to each of the lighting circuits 140a to 140c. There is no shortage of voltage of the duplicate dimming signal. The internal configuration of the dimming signal distribution unit 130 will be described in detail later.

  The lighting circuit 140a is a lighting circuit that controls lighting of the light source 150a, and includes a full-wave rectifier 141a, an electrolytic capacitor 142a, a diode 143a, an FET (Field Effect Transistor) 144a, an inductor 145a, and a capacitor 146a. The lighting circuit 140a includes a dimming signal receiving unit 147a and a control unit 148a. Since the lighting circuits 140b and 140c have the same configuration as the lighting circuit 140a, description thereof is omitted.

  The full-wave rectifier 141a rectifies AC power supplied from the AC power supply 110 and converts it into DC power. The electrolytic capacitor 142a is connected to the positive and negative electrodes of the full wave rectifier 141a, and smoothes the DC power obtained by the full wave rectifier 141a. In the present embodiment, the full-wave rectifier 141a and the electrolytic capacitor 142a operate as a rectifier circuit.

  The diode 143a forms a closed circuit together with the inductor 145a and the capacitor 146a, and charges the capacitor 146a with the current from the inductor 145a when the FET 144a is in a non-conductive state.

  The FET 144a is a switching element driven by the control of the control unit 148a, and is connected in series with the full-wave rectifier 141a, the inductor 145a, and the capacitor 146a. The FET 144a switches between the conductive state and the non-conductive state according to the control of the control unit 148a. When the FET 144a is in a conductive state, the FET 144a charges the inductor 145a with DC power smoothed by the electrolytic capacitor 142a.

  The inductor 145a is charged when the FET 144a is conductive, and is discharged when the FET 144a is non-conductive. As described above, the inductor 145a is discharged when the FET 144a is in a non-conductive state, whereby the capacitor 146a is charged via the diode 143a.

  The capacitor 146a is charged when the FET 144a is in a non-conducting state, thereby smoothing DC power and lighting the light source 150a with a charging voltage. That is, the light source 150a is connected to both ends of the capacitor 146a, and the light source 150a is turned on by the current from the capacitor 146a.

  The dimming signal receiving unit 147a receives the duplicate dimming signal output from the dimming signal distribution unit 130, and outputs dimming information for dimming indicated by the duplicate dimming signal to the control unit 148a. That is, when the duplicate dimming signal is a PWM dimming signal, for example, the dimming signal receiving unit 147a outputs a pulse similar to the pulse of the duplicate dimming signal to the control unit 148a.

  The control unit 148a includes control components such as a microcomputer (microcontroller or microcomputer) and a processor, for example, and drives the FET 144a according to the dimming information output from the dimming signal receiving unit 147a. That is, for example, when a PWM-based duplicate dimming signal is received by the dimming signal receiving unit 147a, the control unit 148a switches between the conductive state and the non-conductive state of the FET 144a according to the duty ratio of the duplicate dimming signal. Thereby, the time ratio of the lighting time of the light source 150a and the light extinction time is adjusted, and as a result, the light quantity of the light source 150a is adjusted.

  FIG. 2 is a diagram illustrating a configuration of the dimming signal distribution unit 130 according to the present embodiment. The dimming signal distribution unit 130 illustrated in FIG. 2 includes a resistor 201, a full-wave rectifier 202, transformers 203a to 203c, diodes 204a to 204c, resistors 205a to 205c, resistors 206a to 206c, and FETs 207a to 207c.

  The resistor 201 is connected to a dimmer (not shown) and a dimming signal line, and the current value of the dimming signal input to the lighting device having one lighting circuit and one light source ( For example, it is adjusted to 4 mA). Therefore, although the illuminating device which concerns on this embodiment is provided with the three lighting circuits 140a-140c, the electric current which flows into a light control signal line becomes the same as the case where the illuminating device is provided with one lighting circuit.

  The full-wave rectifier 202 rectifies the dimming signal and outputs it to the transformers 203a to 203c. The transformers 203a to 203c include one primary coil on the input side and three secondary coils on the output side, and generate a duplicate dimming signal having a predetermined voltage value from the dimming signal. In the present embodiment, since the lighting device 120 includes the three lighting circuits 140a to 140c, the transformers 203a to 203c generate a duplicate dimming signal in each of the three secondary coils. The duplicate dimming signal includes the same dimming information as the dimming signal input to the dimming signal distributor 130. Therefore, when the dimming signal input to the dimming signal distribution unit 130 is, for example, a PWM dimming signal, the duty ratios of the dimming signal and the duplicate dimming signals correspond to each other.

  In addition, although the different code | symbol is attached | subjected corresponding to each secondary coil for convenience of explanation, transformer 203a-203c may be integrally formed as a whole. One end of each secondary coil of the transformers 203a to 203c is connected to the ground, and the other end is connected to the anode terminals of the diodes 204a to 204c, respectively.

  The diodes 204a to 204c supply a current corresponding to the duplicate dimming signal generated in the transformers 203a to 204c to the resistors 205a to 205c. Specifically, when the duplicate dimming signal is, for example, a PWM dimming signal, the diodes 204a to 204c supply current to the resistors 205a to 205c in a period in which the signal level is high.

  The resistors 205a to 205c are connected between the cathode terminals of the diodes 204a to 204c and the gate terminals of the FETs 207a to 207c. The resistors 205a to 205c adjust the gate voltage applied to the gate terminals of the FETs 207a to 207c by the current supplied from the diodes 204a to 204c. That is, the resistors 205a to 205c apply an appropriate gate voltage exceeding the gate threshold voltage to the gate terminals of the FETs 207a to 207c in a period in which the signal level is high when the duplicate dimming signal is, for example, a PWM dimming signal. .

  The resistors 206a to 206c are connected to the ground, and discharge unnecessary charges to the ground. Specifically, when the duplicate dimming signal is, for example, a PWM dimming signal, the resistors 206a to 206c are charged with a charge corresponding to a voltage that is less than the gate threshold voltage of the FETs 207a to 207c during the low signal level period. Release to ground.

The FETs 207a to 207c are switched between a conductive state and a nonconductive state by a gate voltage applied from the resistors 205a to 205c. Specifically, when the signal level of the duplicate dimming signal is high, the FETs 207a to 207c are turned on because the gate voltage applied from the resistors 205a to 205c exceeds the gate threshold voltage. As a result, at the drain terminals of the FETs 207a to 207c, the potential becomes equal to the ground potential. For example, a potential difference occurs between the positive terminal connected to the power supply voltage ∨ _{CC of} 12∨, and the amplified replicas are amplified. A dimming signal is output. That is, a duplicate dimming signal amplified to a voltage substantially the same as the voltage of the dimming signal input to the dimming signal distribution unit 130 is output.

  FIG. 3 is a diagram illustrating a configuration of the dimming signal receiving unit 147a according to the present embodiment. The dimming signal receiving unit 147a illustrated in FIG. 3 includes a resistor 301, a full-wave rectifier 302, a photocoupler 303, and a resistor 304.

  The resistor 301 adjusts the current value of the duplicate dimming signal output from the dimming signal distribution unit 130. In this embodiment, since the duplicate dimming signal is amplified by the dimming signal distribution unit 130, the voltage applied to the resistor 301 is the voltage of the dimming signal input to the dimming signal distribution unit 130. And there is no shortage of voltage. In other words, even if the current value of the dimming signal input to the dimming signal distribution unit 130 is equal to the current value of the dimming signal input to the lighting device having only one light source, the three lighting circuits 140a. ˜140c is input with a duplicate dimming signal having a voltage sufficient for dimming.

  The full-wave rectifier 302 rectifies the duplicate dimming signal and outputs it to the photocoupler 303. The photocoupler 303 outputs a duplicate dimming signal to the control unit 148a while insulating the input and output of the dimming signal receiving unit 147a. That is, in the photocoupler 303, for example, the internal transistor is in a conductive state when the signal level of the PWM-type duplication dimming signal is high, and the internal level is low when the signal level of the duplication dimming signal is low. The transistor is turned off.

Resistor 304 is provided, for example, between the power supply voltage ∨ _DD photocoupler 303 5∨, the photocoupler 303 inside the transistor current flow during a conductive state. Here, when the transistor in the photocoupler 303 is in a conductive state, a current flows through the transistor, so that the potential of the output terminal to the control unit 148a becomes equal to the ground potential. On the other hand, when the transistor in the photocoupler 303 is non-conductive, the potential of the output terminal to the control unit 148a becomes higher than the ground potential. As a result, information on the pulse of the duplicate dimming signal received by the dimming signal receiving unit 147a is transmitted to the control unit 148a.

  However, when the signal level of the duplicate dimming signal input to the dimming signal receiving unit 147a becomes high, the transistor in the photocoupler 303 becomes conductive, and the potential of the output terminal to the control unit 148a becomes low. . For this reason, the dimming signal received by the dimming signal receiving unit 147a and the signal output to the control unit 148a are inverted in pulse high and low.

  Since the control unit 148a drives the FET 144a based on the signal output from the dimming signal receiving unit 147a, the FET 144a is in a non-conducting state when the period during which the signal level is high in the duplicate dimming signal becomes relatively long. Is relatively long. As a result, when the turn-off time of the light source 150a is relatively long and the period during which the signal level is high in the duplicate dimming signal is relatively long, the light amount of the light source 150a is reduced.

  Next, the operation of the lighting device 120 according to the present embodiment will be described with reference to the flowchart shown in FIG.

  A dimming signal output from a dimmer (not shown) is input to the dimming signal distribution unit 130 (step S101). At this time, the current value of the dimming signal is adjusted to a value equal to the current value of the dimming signal for one lighting circuit by the resistor 201 in the dimming signal distribution unit 130. That is, the dimmer (not shown) supplies a current for one lighting circuit to the lighting device 120 including the three lighting circuits 140a to 140c. Therefore, even if the lighting device includes a plurality of lighting circuits, the current value supplied to the lighting device by the dimmer does not increase, and the number of lighting devices that can be connected to the dimmer does not decrease. .

  The dimming signal input to the dimming signal distribution unit 130 is duplicated by the transformers 203a to 203c in the dimming signal distribution unit 130, and three duplicate dimming signals including the same dimming information as the dimming signal are obtained. It is generated (step S102). That is, the dimming signal distribution unit 130 generates three duplicate dimming signals corresponding to the three lighting circuits 140a to 140c from one dimming signal. Here, the voltage value of the duplicate dimming signal may be lower than the voltage value of the dimming signal input to the dimming signal distribution unit 130.

The three duplicate dimming signals are each amplified when output from the dimming signal distribution unit 130 (step S103). Specifically, the voltage of the duplicate dimming signal is amplified by the power supply voltage ∨ _CC (for example, 12 ∨) in the dimming signal distribution unit 130 and is substantially the same pulse as the dimming signal input to the dimming signal distribution unit 130. A duplicate dimming signal having a width and voltage is obtained. These duplicate dimming signals are output to the dimming signal receiving units 147a to 147c of the lighting circuits 140a to 140c, respectively.

  When the duplicate dimming signal is received by the dimming signal receiving units 147a to 147c, dimming information indicated by the duplicate dimming signal is transmitted to the control units 148a to 148c, respectively. Then, the control units 148a to 148c drive the FETs 144a to 1434c according to the transmitted dimming information (step S104). That is, when the duplicate dimming signal is a PWM type pulse signal, the conductive state and non-conductive state of the FET 144a are switched according to the duty ratio of the pulse signal. As a result, the ratio of the turn-on time and the turn-off time of the light source 150a is adjusted to change the light amount, and the light source 150a is dimmed according to the duplicate dimming signal.

  Thus, the current value of the dimming signal input to the dimming signal distribution unit 130 is equal to the current value of the dimming signal for one lighting circuit, but the dimming signal distribution unit 130 generates a duplicate dimming signal. And the amplified dimming signal is output to the lighting circuits 140a to 140c, respectively. Therefore, in each of the lighting circuits 140a to 140c, a duplicate dimming signal having substantially the same pulse width and voltage as the dimming signal input from the dimmer (not shown) to the dimming signal distribution unit 130 is input. Become. As a result, in each of the lighting circuits 140a to 140c, there is no shortage of voltage of the duplicate dimming signal, and reliable dimming is performed. At the same time, since the current supplied from the dimmer (not shown) to the lighting device according to the present embodiment is equal to the current supplied to the lighting device including one lighting circuit, the lighting device that can be connected to the dimmer The number never decreases.

  As described above, according to the first embodiment, in a lighting device including a plurality of lighting circuits, a dimming signal is duplicated to generate and amplify a number of duplicate dimming signals equal to the number of lighting circuits, Output to each lighting circuit. For this reason, even if the current value of the dimming signal output from the dimmer is the current value for one lighting circuit, a dimming signal having a sufficient current value is input to each lighting circuit. And even if the number of lighting circuits in the lighting device increases, the current value supplied from the dimmer to the lighting device does not increase, so the number of lighting devices that can be connected to the dimmer does not change. That is, according to this embodiment, it is possible to prevent a decrease in the number of lighting devices that can be connected to one dimmer.

(Second Embodiment)
A feature of the second embodiment is that a duplicate dimming signal is generated from a dimming signal using a microcomputer. Since the configuration of the illumination device according to the present embodiment is the same as that of the illumination device according to the first embodiment (FIG. 1), description thereof is omitted. However, in the present embodiment, the configuration of the dimming signal distribution unit 130 is different from that of the first embodiment.

  FIG. 5 is a diagram illustrating a configuration of the dimming signal distribution unit 130 according to the present embodiment. 5, the same parts as those in FIG. 2 are denoted by the same reference numerals, and the description thereof is omitted. The dimming signal distribution unit 130 illustrated in FIG. 5 includes a resistor 201, a full-wave rectifier 202, a photocoupler 501, a resistor 502, a microcomputer 503, resistors 504a to 504c, and FETs 505a to 505c.

  The photocoupler 501 outputs a dimming signal to the microcomputer 503 while insulating the input and output of the dimming signal distribution unit 130. That is, in the photocoupler 501, for example, when the signal level of the PWM dimming signal is high, the internal transistor is in a conductive state, and when the signal level of the dimming signal is low, the internal transistor is It becomes a non-conductive state.

Resistor 502 is provided, for example, between the power supply voltage ∨ _DD photocoupler 501 5∨, photocoupler 501 inside the transistor current flow during a conductive state. Here, when the transistor in the photocoupler 501 is in a conductive state, a current flows through the transistor, so that the potential of the output terminal to the microcomputer 503 becomes equal to the ground potential. On the other hand, when the transistor in the photocoupler 501 is non-conductive, the potential of the output terminal to the microcomputer 503 is higher than the ground potential. As a result, information related to the pulse of the dimming signal input to the dimming signal distribution unit 130 is transmitted to the microcomputer 503.

  The microcomputer 503 duplicates the dimming signal input to the dimming signal distribution unit 130 and generates three duplicate dimming signals including the same dimming information as the dimming signal. However, the voltage of the duplicate dimming signal generated by the microcomputer 503 may not be the same as the voltage of the dimming signal input to the dimming signal distribution unit 130. In other words, the microcomputer 503 generates a duplicate dimming signal including the same dimming information as the dimming information included in the dimming signal within the range of the supplied power supply voltage (for example, 5∨). Therefore, the microcomputer 503 normally generates a duplicate dimming signal having a voltage smaller than that of the dimming signal input to the dimming signal distribution unit 130. Then, the microcomputer 503 outputs the generated three duplicate dimming signals to the resistors 504a to 504c, respectively.

The resistors 504a to 504c apply a gate voltage to the FETs 505a to 505c in accordance with the duplicate dimming signal generated by the microcomputer 503. The FETs 505a to 505c switch between a conductive state and a non-conductive state according to a voltage corresponding to the duplicate dimming signal generated by the microcomputer 503. Specifically, when the signal level of the duplicate dimming signal is high, the gate voltages applied from the resistors 504a to 504c become high and the FETs 505a to 505c become conductive. As a result, at the drain terminals of the FETs 505a to 505c, the potential becomes equal to the ground potential. For example, a potential difference is generated with the positive output terminal connected to the power supply voltage ∨ _{CC of} 12∨, and the amplified duplication dimming A signal is output.

  In the present embodiment, the dimming signal input to the dimming signal distribution unit 130 is duplicated by the microcomputer 503, and the obtained duplicate dimming signal is amplified and output to each of the lighting circuits 140a to 140c. For this reason, even if the current value of the dimming signal input to the dimming signal distribution unit 130 is equal to the current value of the dimming signal for one lighting circuit, each lighting circuit 140a to 140c has a sufficient voltage. A duplicated dimming signal amplified is input to. As a result, the three lighting circuits 140a to 140c receive a duplicate dimming signal having a voltage sufficient for dimming, and the dimming of the light sources 150a to 150c is reliably controlled.

  In the present embodiment, since the microcomputer 503 generates a duplicate dimming signal, it is possible to change the method of the dimming signal and the duplicate dimming signal at the input / output of the dimming signal distribution unit 130. is there. That is, when the dimming signal input to the dimming signal distribution unit 130 is a signal conforming to a communication protocol such as DMX512, for example, the microcomputer 503 uses the PWM method without impairing the dimming information included in the dimming signal. It is also possible to generate a duplicate dimming signal.

  More specifically, for example, when the lighting circuits 140a to 140c and the light sources 150a to 150c correspond to RGB three-color LEDs, according to a communication protocol such as DMX512, dimming of the LEDs of the respective colors is performed. It can be controlled individually. That is, the dimming signal conforming to the communication protocol such as DMX512 includes dimming information for dimming differently for each of the light sources 150a to 150c. Therefore, the microcomputer 503 decomposes the dimming information into dimming information for each light source, and generates a PWM-type duplicate dimming signal including the dimming information for each light source. Then, by outputting the duplicate dimming signal for each light source to the lighting circuits 140a to 140c, the dimming of each of the light sources 150a to 150c can be individually controlled. In this case, the circuit configuration of the lighting circuits 140a to 140c may be a relatively simple circuit configuration corresponding to the PWM dimming signal, and it is not necessary to provide a complicated lighting circuit corresponding to the DMX512 or the like.

  As described above, according to the second embodiment, in a lighting device including a plurality of lighting circuits, a dimming signal is duplicated using a microcomputer, and the number of duplicate dimming signals equal to the number of lighting circuits is provided. Output to each lighting circuit. For this reason, even if the current value of the dimming signal output from the dimmer is the current value for one lighting circuit, a dimming signal having a sufficient current value is input to each lighting circuit. And even if the number of lighting circuits in the lighting device increases, the current value supplied from the dimmer to the lighting device does not increase, so the number of lighting devices that can be connected to the dimmer does not change. That is, according to this embodiment, it is possible to prevent a decrease in the number of lighting devices that can be connected to one dimmer.

  Further, according to the second embodiment, the method of the dimming signal output from the dimmer is converted to generate a duplicate dimming signal of a method different from the output of the dimmer, and is supplied to each lighting circuit. It can also be output.

  As described above, according to the first and second embodiments, it is possible to prevent a decrease in the number of lighting devices that can be connected to one dimmer.

  In the above-described embodiment, the lighting device is provided with the three lighting circuits 140a to 140c. However, the number of lighting circuits provided in the lighting device is not limited to three. In addition, the dimming signal and the duplicate dimming signal do not need to be dimming signals conforming to the PWM system or DMX512, and the present invention can be applied to dimming signals of various systems.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 110 AC power supply 120 Lighting device 130 Dimming signal distribution part 140a-140c Lighting circuit 141a-141c, 202, 302 Full wave rectifier 142a-142c Electrolytic capacitor 143a-143c, 204a Diode 144a-144c FET
145a to 145c Inductor 146a to 146c Capacitor 147a to 147c Dimming signal receiving unit 148a to 148c Control unit 150a to 150c Light source 201, 205a to 205c, 206a to 206c, 301, 304, 502, 504a to 504c Resistance 203a to 204c Transformer 303, 501 Photocoupler 503 Microcomputer

Claims (7)

A plurality of lighting control units that are provided corresponding to the plurality of light sources and control the lighting of the light sources;
A dimming signal including dimming information related to dimming of the light source is input, and the dimming signal is duplicated to generate the same number of duplicate dimming signals as the number of the lighting control units. A distribution unit that amplifies and distributes each of the duplicate dimming signals to the plurality of lighting control units;
A lighting device comprising: The distributor is
A transformer including a primary coil to which a dimming signal is input and the same number of secondary coils as the plurality of lighting control units is generated, and a duplicate dimming signal is generated in each of the secondary coils. The lighting device according to claim 1. The distributor is
The lighting device according to claim 1, further comprising: a control component that generates a duplicate dimming signal based on dimming information included in the dimming signal. The distributor is
The dimming information included in the dimming signal is decomposed into dimming information for each of the plurality of light sources, and a duplicate dimming signal including the dimming information for each of the obtained light sources is generated. Lighting device. The distributor is
5. The lighting device according to claim 1, wherein the voltage of the generated duplicate dimming signal is amplified and distributed to substantially the same voltage as the voltage of the dimming signal. With multiple light sources;
A lighting device according to any one of claims 1 to 5;
An illumination device comprising: A dimming method in a lighting device that is provided corresponding to a plurality of light sources and includes a plurality of lighting control units that control lighting of the light sources,
An input step in which a dimming signal including dimming information related to dimming of the light source is input;
A generation step of duplicating the input dimming signal to generate the same number of duplicate dimming signals as the number of the lighting control units;
A distributing step of amplifying and distributing each of the generated duplicate dimming signals to the plurality of lighting control units;
A control step of controlling lighting of the plurality of light sources according to the distributed duplication dimming signal;
The light control method characterized by comprising.

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