JP2009259542A - Lighting device and illumination device, and illumination control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To use a power supply line to input an instruction for changing the lighting state of a lamp to a lighting device without turning the lamp off. <P>SOLUTION: A power supply detecting circuit 160 detects whether or not a DC power supply circuit 110 receives an AC voltage. An off-period measuring section 171 measures a length of a power-off period. An off-operation determining section 172 determines whether or not a power-off operation takes place. The lighting control section 173 generates a control signal for changing the lighting state of a discharge lamp LA if a predetermined number of power-off operations are performed. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a lighting device capable of changing a lighting state of a lamp such as a discharge lamp.

In order to reduce the power consumed by the luminaire, it is effective to appropriately adjust the brightness (illuminance) of the lamp.
Therefore, there is a lighting device having a dimming function.
JP-A-3-269996

In order to realize the dimming function, it is necessary to add a function for inputting a user's dimming command to the lighting device.
If a dedicated wiring is provided for inputting the dimming command, it takes time to install the luminaire and the installation cost increases.
In the method of inputting the user's dimming command to the lighting device by operating the power switch, if the operation takes time, the lamp may be turned off during the dimming command input.
The present invention has been made, for example, in order to solve the above-described problems, and an object thereof is to input a dimming command to a lighting device without turning off the lamp.

The lighting device according to this invention is
A DC power supply circuit that inputs AC voltage and generates DC voltage from the input AC voltage;
A smoothing capacitor charged by a DC voltage generated by the DC power supply circuit;
A power supply detection circuit for detecting whether or not the DC power supply circuit is inputting an AC voltage;
Based on the detection result detected by the power supply detection circuit, when the DC power supply circuit does not input an AC voltage and then the DC power supply circuit inputs an AC voltage, the DC power supply circuit inputs an AC voltage. An off-period measurement unit that measures the length of the period that did not exist,
When the length of the period measured by the off period measurement unit is within a predetermined range, an off operation determination unit that determines that there has been one power off operation,
A lighting control unit that generates a control signal for changing the lighting state of the lamp when it is determined that a predetermined number of power-off operations have been performed within a predetermined period based on the determination result determined by the off operation determination unit. When,
And a lighting circuit that generates electric power to be supplied to the lamp from a DC voltage charged in the smoothing capacitor based on a control signal generated by the lighting control unit.

  According to the lighting device of the present invention, a command for changing the lighting state of the lamp is input to the lighting device without turning off the lamp by an operation pattern in which the power-off operation for turning off the power switch for a short time is repeated a predetermined number of times. There is an effect that can be.

Embodiment 1 FIG.
Embodiment 1 will be described with reference to FIGS.
The lighting control system 850 includes a lighting fixture 800 and a lighting control device 200.

FIG. 1 is a perspective view showing an external appearance of a lighting fixture 800 in this embodiment.
The lighting fixture 800 has a lamp socket 810 for connecting a discharge lamp (lamp), and a voltage generated by the built-in discharge lamp lighting device is applied to the discharge lamp LA connected to the lamp socket 810 to release the lamp. Turn on the lamp LA.

FIG. 2 is a block configuration diagram showing the overall configuration of the illumination control system 850 in this embodiment.
The lighting control device 200 operates by receiving power from an AC power source AC such as a commercial power source. The lighting control device 200 inputs a user command and generates a signal for controlling the lighting fixture 800 according to the input command.
The illumination control device 200 includes an operation input device 210, a control power supply circuit 250, a microcomputer 270, and a switch device 230.

The operation input device 210 is a device for inputting a command that the user wants to input to the lighting fixture 800 with a simple operation. The operation input device 210 has operation buttons corresponding to operations such as “100% lighting”, “75% lighting”, and “50% lighting”, and the user inputs a desired operation by pressing the operation button. To do. Alternatively, the operation input device 210 includes an infrared light receiving unit, and when the user presses an operation button of the infrared remote control and the infrared light receiving unit receives an infrared signal transmitted by the infrared remote control, an operation desired by the user is received. May be entered.
The operation input device 210 generates and outputs an operation signal representing the input operation.

The control power supply circuit 250 receives an AC voltage from the AC power supply AC, and generates a control power supply voltage serving as a power supply for operating the microcomputer 270 from the input AC voltage.
The microcomputer 270 operates using the control power supply voltage generated by the control power supply circuit 250 as a power supply, and implements the function of the operation pattern generation unit 271 by executing a program stored in a storage device such as a ROM (not shown). . Note that the operation pattern generation unit 271 may be realized by an analog circuit, a digital circuit, an analog-digital mixing circuit, or the like, instead of being realized by the microcomputer 270 executing a program.

  The operation pattern generation unit 271 receives the operation signal generated by the operation input device 210, and generates a switch opening / closing signal having a predetermined pattern corresponding to the user operation based on the user operation represented by the input operation signal. To do. The open / close pattern of the switch open / close signal generated by the operation pattern generation unit 271 is, for example, how many times an off period of a short time (for example, 100 milliseconds to 500 milliseconds) and a subsequent on period (for example, 200 milliseconds). It is a repeating pattern. When the operation input device 210 does not input a user operation and does not generate an operation signal, the operation pattern generation unit 271 generates a switch open / close signal that keeps the on state.

The switch device 230 includes a switch using a semiconductor contact such as a solid state relay or a mechanical contact such as an electromagnetic relay. The switch of the switch device 230 is electrically connected in series with the AC power supply AC when viewed from the lighting fixture 800, and an AC voltage is supplied to the lighting fixture 800 from the AC power supply AC via the switch device 230. For this reason, when the switch device 230 is turned off, AC voltage is not supplied to the lighting fixture 800 from the AC power supply AC, and when the switch device 230 is turned on (if the power switch SW is also turned on), the lighting fixture 800 is AC switched. An AC voltage is supplied from the power source AC.
The switch device 230 receives the switch open / close signal generated by the operation pattern generation unit 271 and opens / closes the switch based on the input switch open / close signal.

The lighting fixture 800 is connected to the AC power supply AC via the lighting control device 200, receives power from the AC power supply AC, and lights the discharge lamp LA connected to the lamp socket 810.
The lighting fixture 800 includes a discharge lamp lighting device 100. The discharge lamp lighting device 100 receives an AC voltage from an AC power supply AC, and generates a voltage to be applied to the discharge lamp LA from the input AC voltage.
When the lighting control device 200 turns off the switch device 230, the discharge lamp lighting device 100 continues to turn on the discharge lamp LA because the switch device 230 is off for a short time. In addition, when the user turns off the power switch SW, the discharge lamp lighting device 100 turns off the discharge lamp LA because the power switch SW is off for a long time.
The discharge lamp lighting device 100 inputs a control signal from the illumination control device 200 by using a short-time power off that does not turn off the discharge lamp LA. The lighting control device 200 inputs a command to change the lighting state of the discharge lamp LA such as the brightness of the discharge lamp LA by turning off the power of the lighting fixture 800 according to a predetermined pattern, and the discharge lamp lighting device 100 changes the lighting state of the discharge lamp LA according to the power-off pattern.

The discharge lamp lighting device 100 includes a DC power supply circuit 110, a smoothing capacitor C24, an inverter circuit 130, a coil L41, a capacitor C42, a capacitor C43, a control power supply circuit 150, a power supply detection circuit 160, a microcomputer 170, and a nonvolatile memory 180.
The DC power supply circuit 110 receives a low-frequency AC voltage (for example, 50 Hz to 60 Hz, 100 V to 254 V) from an AC power supply AC such as a commercial power supply, and generates a DC voltage (for example, 400 V) from the input low-frequency AC voltage. The DC power supply circuit 110 includes a diode bridge DB, a choke coil L21, a switching element Q22, a diode D23, and a boost control circuit PFC. The diode bridge DB generates a pulsating voltage by full-wave rectifying a low-frequency AC voltage, An active filter circuit (boost chopper circuit) composed of the choke coil L21, the switching element Q22, the diode D23, and the boost control circuit PFC boosts the pulsating voltage to generate a DC voltage.
The smoothing capacitor C24 is charged with a DC voltage generated by the DC power supply circuit 110.
The inverter circuit 130 (lighting circuit) receives the DC voltage charged in the smoothing capacitor C24, and generates a high-frequency AC voltage (for example, 50 kHz to 80 kHz) from the input DC voltage. The inverter circuit 130 is, for example, a half bridge circuit including a switching element Q31, a switching element Q32, and a drive circuit 135. The drive circuit 135 receives a control signal, and generates a high-frequency AC rectangular wave voltage by alternately turning on and off the switching element Q31 and the switching element Q32 based on the input control signal.
The coil L41 is a choke coil that limits the current flowing through the discharge lamp LA.
The capacitor C42 is a coupling capacitor that cuts the DC component of the high-frequency AC voltage generated by the inverter circuit 130.
Capacitor C43 is a starting capacitor that starts a discharge of discharge lamp LA by generating a high voltage between filaments of discharge lamp LA by resonating with coil L41 and capacitor C42 when starting discharge lamp LA.

  The control power supply circuit 150 generates a DC voltage (for example, 5 V) that serves as a power supply for operating the microcomputer 170. The control power supply circuit 150 receives, for example, a pulsating voltage that is full-wave rectified by the diode bridge DB, and steps down the input pulsating voltage to generate a DC voltage (hereinafter referred to as “control power supply voltage”). Note that the control power supply circuit 150 is configured so that the microcomputer 170 can continue to operate for several minutes (for example, 5 minutes) even after the discharge lamp lighting device 100 stops inputting the AC voltage from the AC power supply AC. Continue to generate. For example, the control power supply circuit 150 includes a capacitor that is charged by the generated control power supply voltage, and uses the voltage charged in the capacitor as a power supply for operating the microcomputer 170.

  The power supply detection circuit 160 detects whether or not the DC power supply circuit 110 is inputting an AC voltage, and generates a power supply detection signal representing the detection result. The power supply detection circuit 160 receives, for example, a pulsating voltage obtained by full-wave rectification by the diode bridge DB, and when the input voltage is higher than a predetermined voltage (hereinafter referred to as “power supply detection threshold voltage”), the DC power supply circuit 110 generates a power supply detection signal (hereinafter referred to as “H”) indicating that an AC voltage is input. When the input voltage is lower than the power supply detection threshold voltage, the DC power supply circuit 110 generates an AC voltage. A power supply detection signal (hereinafter referred to as “L”) indicating that no is input is generated.

  The microcomputer 170 operates using the control power supply voltage generated by the control power supply circuit 150 as a power supply, and executes a program stored in a storage device such as a ROM (not shown), whereby an off period measuring unit 171 and an off operation determining unit 172, the function of the lighting control unit 173 is realized. The off period measuring unit 171, the off operation determining unit 172, and the lighting control unit 173 are not realized by the microcomputer 170 executing the program, but are realized by an analog circuit, a digital circuit, an analog / digital mixing circuit, or the like. Also good.

The nonvolatile memory 180 stores data written by the microcomputer 170. The non-volatile memory 180 holds the stored data even when the discharge lamp lighting device 100 stops inputting an AC voltage from the AC power supply AC.
The state storage unit 181 stores data representing the lighting state of the discharge lamp LA using the nonvolatile memory 180.

The off period measuring unit 171 receives the power detection signal generated by the power detection circuit 160, and measures the length of the power off period based on the detection result of the power detection circuit 160 represented by the input power detection signal. The power-off period is a period during which the discharge lamp lighting device 100 temporarily stops inputting AC voltage from the AC power source AC due to the switch device 230 being turned off. As described above, even after the discharge lamp lighting device 100 stops inputting AC voltage from the AC power supply AC, the microcomputer 170 continues to operate for several minutes, so that the power is turned off longer than the period until the operation of the microcomputer 170 stops. If the period is short, the off period measuring unit 171 can measure the length of the power off period.
For example, the off period measurement unit 171 always monitors whether the power detection signal is “H” or “L”, and measures the elapsed time when the power detection signal changes from “H” to “L”. To start. The off period measuring unit 171 continues to monitor the power detection signal after that, and when the power detection signal changes from “L” to “H” before the maximum off period (for example, 1 second) elapses, After the measurement is completed, the measured elapsed time is set as the length of the power-off period. The “maximum off period” is that the power supply is cut off because the lighting control device 200 turns off the switch device 230 to input a command, or the user turns off the discharge lamp LA. In addition, it is the length of the power-off period serving as a threshold for determining whether or not the power switch SW is operated. The discharge lamp lighting device 100 determines whether the illumination control device 200 is about to input a command or the user is about to turn off the discharge lamp LA until the maximum off period elapses after the supply voltage is not input. Since it is not possible, the lighting of the discharge lamp LA is continued. Therefore, when the user wants to turn off the discharge lamp LA and turns off the power switch SW, the reaction is delayed by the maximum off period. Therefore, it is preferable to set the maximum off period to about 1 second at the longest.

The off operation determination unit 172 determines whether or not a power off operation has been performed based on the length of the power off period measured by the off period measurement unit 171. The power-off operation refers to one-off operation among operations in which the illumination control device 200 turns on / off the switch device 230 according to a predetermined opening / closing pattern. The period during which the switch device 230 is off is, for example, about 100 milliseconds.
Since the pulsating voltage input by the power supply detection circuit 160 becomes 0 every half of the cycle of the low-frequency AC voltage input by the discharge lamp lighting device 100, the power supply detection signal output by the power supply detection circuit 160 is released. Even when the lamp lighting device 100 inputs a low-frequency AC voltage, it becomes “L” at a frequency that is twice the frequency of the low-frequency AC voltage. In this case, since the period during which the power detection signal is “L” is short (for example, within 1 millisecond), the off operation determination unit 172 can distinguish from the power off operation based on the length of the power off period. . That is, the off-operation determining unit 172 has a predetermined range (hereinafter referred to as “power-off operation determination range”) that is long enough to be distinguished from periodic “L” and shorter than the maximum off-period. .) (For example, 5 milliseconds to 1 second), it is determined that there has been a power-off operation. If the length of the power-off period is longer than the power-off operation determination range, there has been a light-off operation. Conversely, if the length of the power-off period is shorter than the power-off operation determination range, it is determined that there has been no operation.

The lighting control unit 173 generates a control signal input by the drive circuit 135. Since the drive circuit 135 operates based on the control signal, the lighting control unit 173 controls the drive circuit 135 and changes the lighting state of the discharge lamp LA by changing the control signal. Based on the determination result determined by the off operation determination unit 172, the lighting control unit 173 determines that the power-off operation has been performed a predetermined number of times (hereinafter referred to as “change operation determination number”) within a predetermined period. In this case, it is determined that there has been a change operation.
Even when the off-operation determining unit 172 determines that there has been a power-off operation, the power detection signal may have become “L” due to a momentary power failure (instantaneous power failure), a sag (instantaneous voltage drop), or the like. . The period during which an instantaneous power failure or sag occurs is, for example, within several tens of milliseconds. If this is within the power-off operation determination range, the off-operation determination unit 172 determines that there has been a power-off operation. Therefore, it is assumed that the command from the lighting control device 200 is expressed only after the power-off operation is performed a plurality of times within a predetermined period instead of a single power-off operation. The change operation is an operation in which the power-off operation is repeated a predetermined number of times. When the lighting control unit 173 determines that the change operation has been performed, the lighting control unit 173 generates a control signal for changing the lighting state of the discharge lamp LA (for example, the brightness of lighting).
The number of change operation determinations is at least twice. If the number of change operation determinations is large, the possibility of erroneous determination due to the influence of momentary power interruption, sag, or the like is reduced. However, since it takes time to transmit the command, it is preferably about 2 to 3 times.

In addition, when the lighting state of the discharge lamp LA is changed, the lighting control unit 173 stores data representing the changed lighting state in the state storage unit 181.
When the discharge lamp lighting device 100 starts to input an AC voltage from the AC power supply AC with the discharge lamp LA turned off, the lighting control unit 173 inputs the data stored in the state storage unit 181 and inputs the data. The lighting state of the discharge lamp LA before the turn-off represented by the data is acquired, and a control signal for making the lighting state of the discharge lamp LA the same lighting state as before the turn-off is generated. Thereby, for example, when the user turns off the light after adjusting the brightness of the discharge lamp LA, when the discharge lamp LA is turned on next time, the discharge lamp LA is turned on with the same brightness as before the light is turned off.

  Next, the operation will be described.

FIG. 3 is a flowchart showing the flow of an operation determination process in which the discharge lamp lighting device 100 according to this embodiment determines the operation content.
The operation determination process is executed from the time when the microcomputer 170 starts operating when the power is turned on until the microcomputer 170 stops operating when the power is turned off.

When the microcomputer 170 starts operating by turning on the power, the processing is executed from the start determination step S611.
In the start determination step S <b> 611, the off period measurement unit 171 receives the power supply detection signal generated by the power supply detection circuit 160. The off period measurement unit 171 determines whether the power detection signal is “H” or “L” based on the input power detection signal.
If it is determined that the power detection signal is “H”, the start determination step S611 is repeated.
When it is determined that the power detection signal is “L”, the process proceeds to the measurement start step S612.

  In the measurement start step S612, the off period measuring unit 171 starts measuring the power off period using a timer or the like.

In the upper limit determination step S613, the off-period measurement unit 171 compares the power-off period in which the measurement is started in the measurement start process S612 with the maximum off period.
If the power off period is longer than the maximum off period, the process proceeds to the extinction determination step S621.
When the power off period is equal to or shorter than the maximum off period, the process proceeds to the end determination step S614.

In the end determination step S614, the off period measurement unit 171 receives the power supply detection signal generated by the power supply detection circuit 160. The off period measurement unit 171 determines whether the power detection signal is “H” or “L” based on the input power detection signal.
When it is determined that the power detection signal is “L”, the process returns to the upper limit determination step S613.
When it is determined that the power detection signal is “H”, the process proceeds to the measurement end step S615.

  In the measurement end step S615, the off period measuring unit 171 ends the measurement of the power off period using a timer or the like.

In the lower limit determination step S616, the off operation determination unit 172 compares the power-off period in which the measurement is ended in the measurement end step S615 with the lower limit of the power-off operation determination range (hereinafter referred to as “minimum off period”).
When the power off period is shorter than the minimum off period, the process returns to the start determination step S611.
If the power off period is equal to or longer than the minimum off period, the process proceeds to the off operation determination step S617.

  In the off operation determination step S617, the off operation determination unit 172 determines that there has been one power-off operation, and outputs data representing the determination result. Then, it returns to start determination process S611.

  In the turn-off determination step S621, the off operation determination unit 172 determines that there has been a turn-off operation, and outputs data representing the determination result.

In the on determination step S622, the off period measuring unit 171 receives the power detection signal generated by the power detection circuit 160. The off period measurement unit 171 determines whether the power detection signal is “H” or “L” based on the input power detection signal.
When it is determined that the power detection signal is “L”, the ON determination step S622 is repeated. In addition, if the time which can continue operation | movement of the microcomputer 170 passes while repeating ON determination process S622, the microcomputer 170 will stop operation | movement and an operation determination process will be complete | finished.
When it is determined that the power detection signal is “H”, the off operation determination unit 172 determines that there is a lighting operation, and outputs data representing the determination result. Then, it returns to start determination process S611.

  FIG. 4 is a flowchart showing the flow of a change operation determination process in which the discharge lamp lighting device 100 in this embodiment determines whether a change operation has been performed.

In the operation acquisition step S631, the lighting control unit 173 waits for the off operation determination unit 172 to output a determination result in the operation determination process, and acquires data representing the determination result output by the off operation determination unit 172.
When the determination result represented by the acquired data indicates that there has been an off operation, the process proceeds to the measurement start step S632.
If the determination result represented by the acquired data is that there is an operation other than the off operation, the process proceeds to the other determination step S637.

  In the measurement start step S632, the lighting control unit 173 starts measuring elapsed time using a timer or the like.

In the interval determination step S633, the lighting control unit 173 compares the elapsed time when measurement was started in the measurement start step S632 with a predetermined time (hereinafter referred to as “operation interval time”), and the operation interval time has elapsed. It is determined whether or not. Note that if the operation interval time is long, the possibility of misjudgment increases due to multiple momentary power interruptions and sags in the meantime, so the operation interval time is less than three times the maximum off time (that is, the power off operation and It is preferable that the period during which the power switch SW is turned on during the power-off operation is not more than twice the maximum off time.
When it determines with operation interval time having passed, it returns to operation acquisition process S631.
If it is determined that the operation interval time has not elapsed, the process proceeds to operation acquisition step S634.

In the operation acquisition step S634, the lighting control unit 173 acquires data representing the determination result output by the off operation determination unit 172 last time, and then turns off if the off operation determination unit 172 outputs a new determination result. Data representing a new determination result output by the operation determination unit 172 is acquired.
When the off operation determination unit 172 does not output a new determination result, the process returns to the interval determination step S633.
When the off operation determination unit 172 outputs a new determination result, and the determination result represented by the acquired data indicates that there is an off operation, the process proceeds to the number determination step S635.
The off operation determination unit 172 outputs a new determination result, and when the determination result represented by the acquired data indicates that there is an operation other than the off operation, the process proceeds to the other determination step S637.

In the number determination step S635, the lighting control unit 173 compares the number of repetitions of the power-off operation with the number of change operation determinations.
When the number of power-off operation repetitions is less than the change operation determination number, the process returns to the measurement start step S632.
If the power-off operation repetition count is equal to the change operation determination count, the process proceeds to the change determination step S636.

  In the change determination step S636, the lighting control unit 173 determines that a change operation has been performed. Thereafter, the change operation determination process ends.

  In other determination process S637, the lighting control unit 173 determines that the same operation as the determination result represented by the data acquired in the operation acquisition process S631 or the operation acquisition process S634 has been performed. Thereafter, the change operation determination process ends.

FIG. 5 is a flowchart showing the flow of a lighting control process in which the discharge lamp lighting device 100 in this embodiment controls lighting and extinguishing of the discharge lamp LA.
The lighting control process is executed after the microcomputer 170 starts operating when the power is turned on until the microcomputer 170 stops operating when the power is turned off.

When the microcomputer 170 starts operating by turning on the power, the processing is executed from the preheating step S641.
In the preheating step S641, the lighting control unit 173 generates and outputs a control signal (hereinafter referred to as “preheating”) instructing to preheat the filament of the discharge lamp LA. As a result, the drive circuit 135 generates a high-frequency AC voltage having a preheating frequency, and the filament of the discharge lamp LA is preheated.
In the preheating end determination step S642, the lighting control unit 173 outputs a control signal “preheating” in the preheating step S641, and then whether or not a predetermined time necessary for sufficiently warming the filament of the discharge lamp LA has elapsed. Determine.
When it is determined that the predetermined time has not elapsed, the preheating end determination step S642 is repeated.
If it is determined that the predetermined time has elapsed, the process proceeds to the starting step S643.

  In the starting step S643, the lighting control unit 173 generates and outputs a control signal (hereinafter referred to as “start”) instructing to start the discharge lamp LA. As a result, the drive circuit 135 generates a high-frequency AC voltage having a starting frequency, and the discharge lamp LA starts discharging and lights up.

In the lighting state acquisition step S644, the lighting control unit 173 acquires data representing the lighting state of the discharge lamp LA before extinguishing, which is stored in the state storage unit 181.
When the lighting state represented by the acquired data is high output lighting, the process proceeds to the high output lighting step S645.
When the lighting state represented by the acquired data is medium output lighting, the process proceeds to medium output lighting step S647.
When the lighting state represented by the acquired data is low output lighting, the process proceeds to the low output lighting step S649.

  In the high output lighting step S645, the lighting control unit 173 generates and outputs a control signal (hereinafter referred to as “high output lighting”) that instructs the discharge lamp LA to be lit at a high output. As a result, the drive circuit 135 generates a high-frequency AC voltage with a high output lighting frequency, and the discharge lamp LA is lit brightest. The state storage unit 181 stores data indicating that the lighting state of the discharge lamp LA is high output lighting.

In the change operation determination step S646, the lighting control unit 173 performs the above-described change operation determination process to determine the operation content.
If it is determined that there has been an extinguishing operation, the process proceeds to the extinguishing step S651.
If it is determined that there has been a change operation, the process proceeds to the medium output lighting step S647.

  In the medium output lighting step S647, the lighting control unit 173 generates and outputs a control signal (hereinafter referred to as “medium output lighting”) that instructs the discharge lamp LA to light at the medium output. As a result, the drive circuit 135 generates a high-frequency AC voltage with a medium output lighting frequency, and the discharge lamp LA lights up slightly darkly. The state storage unit 181 stores data indicating that the lighting state of the discharge lamp LA is medium output lighting.

In the change operation determination step S648, the lighting control unit 173 performs the change operation determination process described above to determine the operation content.
If it is determined that there has been an extinguishing operation, the process proceeds to the extinguishing step S651.
If it is determined that there has been a change operation, the process proceeds to the low output lighting step S649.

  In the low output lighting step S649, the lighting control unit 173 generates and outputs a control signal (hereinafter referred to as “low output lighting”) that instructs the discharge lamp LA to be lit at a low output. As a result, the drive circuit 135 generates a high-frequency AC voltage with a low output lighting frequency, and the discharge lamp LA is lit darkest. The state storage unit 181 stores data indicating that the lighting state of the discharge lamp LA is low output lighting.

In the change operation determination step S650, the lighting control unit 173 performs the above-described change operation determination process to determine the operation content.
If it is determined that there has been an extinguishing operation, the process proceeds to the extinguishing step S651.
If it is determined that there has been a change operation, the process proceeds to the high output lighting step S645.

  In the extinguishing step S651, the lighting control unit 173 generates and outputs a control signal (hereinafter referred to as ““ extinguishing ””) instructing to extinguish the discharge lamp LA. As a result, the drive circuit 135 stops generating the high-frequency AC voltage, and the discharge lamp LA is turned off.

In the change operation determination step S652, the lighting control unit 173 performs the above-described change operation determination process to determine the operation content.
When it determines with there having been lighting operation, it returns to preheating process S641.
When it is determined that there is an operation other than the lighting operation, the change operation determination step S652 is repeated.

  FIG. 6 is a timing chart showing an example of an operation in which the discharge lamp lighting device 100 according to this embodiment determines the operation content.

At time t _1, the user turns on the power switch SW, an AC voltage supplied from the AC power source AC to the discharge lamp lighting device 100. The control power supply circuit 150 generates a control power supply voltage, and the microcomputer 170 starts operation.

Since the voltage value of the pulsating voltage generated by the diode bridge DB is lower than the power supply detection threshold voltage of the power supply detection circuit 160 each time the AC voltage input to the discharge lamp lighting device 100 crosses zero, the power supply detection circuit 160 The detection signal “L” is output. The off period measuring unit 171 measures the power off period, and the off operation determining unit 172 determines that there is no operation because the power off period is shorter than the minimum off period compared to the minimum off period (“T _min ”). To do.

In time t _2, the by the user turns off the power switch SW or instantaneous power failure, an AC voltage from the AC power source AC to the discharge lamp lighting device 100 is not supplied. The inverter circuit 130 continues to generate a high-frequency AC voltage using the voltage charged in the smoothing capacitor C24 as a power source, and the discharge lamp LA continues to be lit. The control power circuit 150 outputs the voltage charged in the internal capacitor as the control power voltage, and the microcomputer 170 continues to operate. The power detection circuit 160 outputs a power detection signal “L”, and the off period measurement unit 171 starts measuring the power off period.

At time t ₃ , the user turns on the power switch SW or recovers from the momentary power interruption, and AC voltage is again supplied from the AC power source AC to the discharge lamp lighting device 100. The power detection circuit 160 outputs a power detection signal “H”, and the power-off period measured by the off-period measuring unit 171 is compared with the minimum off-period by the off-operation determining unit 172. Since it is longer than the period, it is determined that there has been a power-off operation. Since the first power-off operation has been performed, the lighting control unit 173 starts measuring the elapsed time.

At time t _4, the user is or instantaneous power failure has occurred off the power switch SW, immediately, at time t _5, the user to recover from to or instantaneous power failure to turn on the power switch SW. The off period measuring unit 171 measures the power off period, and the off operation determining unit 172 determines that there is no operation because the power off period is shorter than the minimum off period compared to the minimum off period. Actually, it is difficult to intentionally operate the power switch SW within such a short time. For example, when the power switch SW is accidentally touched by mistake and the power switch SW is turned off for a moment. It is.

After that, even if the operation interval time (“T _int ”) has elapsed, there is no next power-off operation, so the lighting control unit 173 determines that there has been no change operation.

At time t _6, the operation input device 210 inputs the user's operation, the operation pattern generation unit 271 generates a closing pattern corresponding to the change operation. According to the opening / closing pattern generated by the operation pattern generation unit 271, the switch device 230 is turned off, and the switch device 230 is turned on at time t ₇ . Since the power-off period is longer than the minimum off-period, the off-operation determining unit 172 determines that there is a power-off operation, and the lighting control unit 173 starts measuring elapsed time.

Switching device 230, in accordance with opening and closing pattern, at time _{t 8,} turned off, at time _{t 9,} is turned on. Since the power off period is longer than the minimum off period, the off operation determination unit 172 determines that the power off operation has occurred, and the lighting control unit 173 performs the power off operation before the operation interval time elapses. It is determined that the power is turned off. For example, if the number of change operation determinations is “2”, the lighting control unit 173 determines that there has been a change operation.

At time _{t 10,} the user turns off the power switch SW. The power detection circuit 160 outputs a power detection signal “L”, and the off period measurement unit 171 starts measuring the power off period.
At time t ₁₁ , even if the maximum off period (“T _max ”) has elapsed, the power detection signal does not become “H”, so the off operation determination unit 172 determines that there has been a turn-off operation.

  FIG. 7 is a timing diagram illustrating an example of an operation in which the discharge lamp lighting device 100 according to this embodiment controls the lighting state of the discharge lamp LA according to a user operation.

At time t _1, the user turns on the power switch SW, the microcomputer 170 starts to operate. The lighting control unit 173 generates a control signal “preheating”, and the inverter circuit 130 generates a high frequency AC voltage having a preheating frequency to preheat the filament of the discharge lamp LA.
Thereafter, the lighting control unit 173 generates a control signal “start”, and the inverter circuit 130 generates a high-frequency AC voltage having a start frequency, and starts discharging the discharge lamp LA.
Assuming that the state storage unit 181 stores data representing “high output lighting” as the previous lighting state of the discharge lamp LA, the lighting control unit 173 generates a control signal “high output lighting”, and the inverter circuit 130 generates a high-frequency AC voltage having a high output lighting frequency, and the discharge lamp LA is lit brightest.

In time t _2, the user operates the operation input device 210 to input an instruction to change the brightness of the discharge lamp LA. The operation input device 210 inputs a change command, and the operation pattern generation unit 271 generates an opening / closing pattern corresponding to the change operation, and the switch device 230 is turned on / off accordingly. The off operation determination unit 172 detects two power-off operations, and the lighting control unit 173 determines that there has been a change operation, and generates a control signal “medium output lighting”. The inverter circuit 130 generates a high-frequency AC voltage with a medium output lighting frequency, and the discharge lamp LA lights up slightly darkly.

At time t ₃ , the operation input device 210 inputs a change command, and the switch device 230 is turned off twice. Therefore, the lighting control unit 173 determines that there is a change operation, and generates a control signal “low output lighting”. . The inverter circuit 130 generates a high-frequency AC voltage with a low output lighting frequency, and the discharge lamp LA is lit darkest.

Then, the user turn off the power switch SW, the power supply switch SW even after the maximum off period does not turn on, at time t _4, off the operation determining unit 172 determines that there has been an off operation, the lighting control unit 173 Generates a control signal “light-off”. The inverter circuit 130 stops generating the high-frequency AC voltage, and the discharge lamp LA is turned off.

At time t _5, it determines that the user has placed the power switch SW, the off operation determining unit 172 had lit operation. The lighting control unit 173 generates a control signal “preheating”, and the inverter circuit 130 generates a high frequency AC voltage having a preheating frequency to preheat the filament of the discharge lamp LA.
Note that when the lighting operation is detected and the filament of the discharge lamp LA is preheated before the microcomputer 170 stops the operation, the lighting control unit 173 does not pass much time since the discharge lamp LA is turned off. The preheating time may be shorter than the preheating time when the microcomputer 170 starts operation.
Thereafter, the lighting control unit 173 generates a control signal “start”, and the inverter circuit 130 generates a high-frequency AC voltage having a start frequency, and starts discharging the discharge lamp LA.
Since the state storage unit 181 stores data representing “low output lighting” as the previous lighting state of the discharge lamp LA, the lighting control unit 173 generates the control signal “low output lighting”, and the inverter circuit 130 generates a high-frequency AC voltage having a low output lighting frequency, and the discharge lamp LA is lit darkest.

At time t ₆ , the operation input device 210 inputs a change command, and the switch device 230 is turned off twice. Therefore, the lighting control unit 173 determines that there is a change operation, and generates a control signal “high output lighting”. . The inverter circuit 130 generates a high-frequency AC voltage having a high output lighting frequency, and the discharge lamp LA is lit brightest.

As described above, the user inputs a command to the discharge lamp lighting device 100 by operating the operation input device 210, and the discharge lamp lighting device 100 controls the lighting state of the discharge lamp LA according to the input command. To do.
In this example, the case where the brightness of the discharge lamp LA is controlled in three stages as the lighting state of the discharge lamp LA has been described. However, the brightness of the discharge lamp LA may be controlled in two stages, or vice versa. In addition, it may be controlled in more stages. Moreover, it is good also as controlling other lighting states instead of the brightness of the discharge lamp LA.
In addition, every time a user inputs a change command, the brightness of the discharge lamp LA is controlled to be switched in the order of high output → medium output → low output → high output. Not limited, low output → middle output → high output → low output, high output → medium output → low output → middle output → high output, or other order .

Next, the maximum off period will be described in detail.
When the user inputs a change command, the discharge lamp lighting device 100 in this embodiment changes the lighting state of the discharge lamp LA while continuing to turn on the discharge lamp LA. Can be confirmed.
For this reason, the maximum OFF period must be shorter than the time during which the discharge lamp lighting device 100 can continue lighting the discharge lamp LA.

When no AC voltage is input from the AC power supply AC to the DC power supply circuit 110, the DC power supply circuit 110 stops generating the DC voltage. The inverter circuit 130 generates a high-frequency AC voltage using the voltage charged in the smoothing capacitor C24 as a power source, and lights the discharge lamp LA.
Here, the capacitance value of the smoothing capacitor C24 is C, and the equivalent resistance value of the circuit including the inverter circuit 130, the coil L41, the capacitor C43, the discharge lamp LA, and the capacitor C42, which is a load viewed from the smoothing capacitor C24, is R. To do. Since the voltage charged in the smoothing capacitor C24 when the DC power supply circuit 110 stops generating the DC voltage is equal to the voltage value _VDC of the DC voltage generated by the DC power supply circuit 110, the DC power supply circuit 110 If the elapsed time after the generation of the DC voltage is stopped is t, the voltage v (t) across the smoothing capacitor C24 can be expressed as follows.

したがって、

If the power consumption value when the discharge lamp LA is lit brightest is W _OUT , the equivalent resistance value R can be expressed as follows.

Therefore,

Assuming that the minimum value of the voltage across the smoothing capacitor C24 that can continue to light the discharge lamp LA (hereinafter referred to as “the minimum voltage that can be lit”) is V _MIN , the time that the discharge lamp LA can be lit continuously (hereinafter “continuous lighting”). Called “possible time”).

For example, the capacitance value C of the smoothing capacitor C24 is 47 μF, the voltage value V _DC of the DC voltage generated by the DC power supply circuit 110 is 400 V, the power consumption value W _OUT of the discharge lamp LA is 40 W, and the minimum voltage value V _{MIN that} can be lit. Is 340V, which is 85% of _VDC , the lighting continuation possible time t is about 40 milliseconds.
Therefore, in this case, the maximum off period is set shorter than 40 milliseconds.

The lighting continuation possible time t becomes longer if the lighting possible minimum voltage value _VMIN is low. For example, in the above example, assuming that the minimum voltage value V _MIN that can be lit is 200 V, which is 50% of _VDC , the lighting continuation possible time t extends to about 160 milliseconds.

The conventional discharge lamp lighting device is designed so that the minimum voltage value V _MIN that can be lit is about 85% of _VDC in consideration of variations in circuit constants.
In the discharge lamp lighting device 100 according to this embodiment, the minimum turn-off voltage value V _MIN is lower than usual (75% or less of _VDC) so that the maximum off period can be set to about 0.2 seconds, for example. (Preferably about 50%).

It should be noted that by increasing the capacitance value C of the smoothing capacitor C24, the lighting continuation possible time t may be lengthened. However, if the capacitance value C of the smoothing capacitor C24 is increased, the discharge lamp lighting device 100 is manufactured. Cost increases.
For this reason, it is preferable to shorten the maximum off period without changing the lighting continuation possible time t, instead of increasing the capacitance value C of the smoothing capacitor C24 to increase the lighting continuation possible time t.
Therefore, it is preferable that the operation pattern generation unit 271 generates an open / close pattern including an off period shorter than the lighting continuation possible time t calculated from Equation 5 as the predetermined operation pattern.

Corresponding to the length of the off period included in the open / close pattern generated by the operation pattern generation unit 271, the minimum off period and the maximum off period for determining the power off operation are determined and set in the off operation determination unit 172.
Here, if one off period is short, it may be difficult to distinguish from instantaneous power failure or sag, but in the discharge lamp lighting device 100 in this embodiment, the power-off operation is repeated the number of times of change operation determination. In this case, since it is determined that there has been a change operation, it is possible to distinguish between the change operation and the instantaneous stop or sag.

Further, in order to distinguish the change operation from the instantaneous power interruption and sag more precisely, for example, the following configuration may be used.
The number of change operation determinations is set to two or more, and the off operation determination unit 172 has a maximum length and a minimum length of the off period in the series of off periods (both the minimum off period and the maximum off period). Difference (that is, variation in the length of the off period). If the off period is caused by turning off the switch device 230 by the lighting control device 200, there is almost no variation in the length of the off period. If the off period is caused by an instantaneous stop or sag, the length of the off period is reduced. There is variation. The off operation determination unit 172 compares the calculated variation in the length of the off period with a predetermined threshold, determines that the variation is small, and determines that the variation is a change operation, and determines that the variation is not a variation, if the variation is large.
Further, the number of change operation determinations is three or more, and the off operation determination unit 172 determines the difference between the maximum and minimum lengths of a plurality of on periods (that is, the on period) between a series of off periods. The variation in the length of the ON period is compared with a predetermined threshold, and if the variation is small, it is determined that the operation is a change operation, and if the variation is large, it is determined that the operation is not a change operation. It is good also as composition to do.

  The lighting device (discharge lamp lighting device 100) in this embodiment includes an AC voltage (low frequency AC voltage), a DC power supply circuit 110 that generates a DC voltage from the input AC voltage, and the DC power supply circuit 110. Based on the smoothing capacitor C24 that is charged by the generated DC voltage, the power detection circuit 160 that detects whether or not the DC power supply circuit 110 is inputting AC voltage, and the detection result detected by the power supply detection circuit 160. When the DC power supply circuit 110 does not input an AC voltage and then the DC power supply circuit 110 inputs an AC voltage, a period during which the DC power supply circuit 110 does not input an AC voltage (power-off period) The length of the off period measuring unit 171 that measures the length and the period (power off period) measured by the off period measuring unit is within a predetermined range (power off operation determination range). ), The off-operation determining unit 172 that determines that there has been a single power-off operation, and the determination result determined by the off-operation determining unit 172 within a predetermined period ( When it is determined that there has been a power-off operation for the number of change operation determination times), a lighting control unit 173 that generates a control signal for changing the lighting state of the lamp (discharge lamp LA), and a control signal generated by the lighting control unit 173 And a lighting circuit (inverter circuit 130) for generating electric power (high frequency AC voltage) to be supplied to the lamp (discharge lamp LA) from the DC voltage charged in the smoothing capacitor C24. Turns on a command to change the lighting state of the lamp (discharge lamp LA) according to an operation pattern in which a power-off operation for turning off the switch device 230 for a short time is repeated a predetermined number of times. An effect that can be input to the location (the discharge lamp lighting device 100).

In this embodiment, the off operation determining unit 172 has an upper limit (maximum off period) of a predetermined range (power off operation determining range) for determining the power off operation by the operation of the lighting circuit (inverter circuit 130). Since the time charged until the voltage charged in the smoothing capacitor C24 is discharged and becomes a predetermined voltage (lowest voltage value V _{MIN that} can be lit) is shorter than the time t, during the power-off operation, the lamp (discharge lamp LA) The lighting can be continued, and the user can immediately visually confirm the result of changing the lighting state of the lamp (discharge lamp LA).

ただし、Ｃは、上記平滑コンデンサの静電容量値。Ｖ_ＤＣは、上記直流電源回路が生成する直流電圧の電圧値。Ｗ_ＯＵＴは、上記ランプの最大消費電力値。ｅは、自然対数の底。Ｖ_ＭＩＮは、上記点灯回路が入力する電圧の、上記ランプの点灯を維持できる最低電圧値である。 The off operation determination unit 172 in this embodiment has a time when the upper limit (maximum off period) of the predetermined range for determining the power off operation (power off operation determination range) is shorter than the time t calculated by Equation 6 Therefore, the lamp (discharge lamp LA) can be continuously lit during the power-off operation, and the user can immediately visually check the result of changing the lighting state of the lamp (discharge lamp LA). .

Where C is the capacitance value of the smoothing capacitor. _VDC is a voltage value of a DC voltage generated by the DC power supply circuit. W _OUT is the maximum power consumption value of the lamp. e is the base of the natural logarithm. V _MIN is the minimum voltage value of the voltage input by the lighting circuit that can maintain the lighting of the lamp.

In the lighting device (discharge lamp lighting device 100) in this embodiment, the minimum value (minimum illuminable voltage value) V _{MIN of the} voltage across the smoothing capacitor C24 that can continue the lighting of the lamp (discharge lamp LA) is as described above. Since it is designed to be 75% or less of the voltage value _VDC of the DC voltage generated by the DC power supply circuit 110, the upper limit (maximum OFF period) of the predetermined range for determining the power-off operation (power-off operation determination range) ) Can be set longer.

  The lighting device (discharge lamp lighting device 100) in this embodiment includes a state storage unit 181 that stores the lighting state of the lamp (discharge lamp LA) changed by the lighting control unit 173, and the lighting control unit 173 includes Based on the detection result detected by the power supply detection circuit 160, when the DC power supply circuit 110 starts to input AC voltage after the lamp (discharge lamp LA) is extinguished, the lamp (discharge lamp LA) Since the control signal for making the lighting state the lighting state stored in the state storage unit 181 is generated, once the lighting state of the lamp (discharge lamp LA) is set once, the same lighting state is automatically set from the next lighting. Thus, there is an effect that the user does not need to adjust the lighting state each time the lamp is lit.

  The lighting fixture 800 in this embodiment includes the lighting device described above (discharge lamp lighting device 100) and the lamp connecting portion (lamp socket 810) that connects the lamp (discharge lamp LA). A command for changing the lighting state of the lamp (discharge lamp LA) connected to the lamp connecting portion may be input to the lighting fixture 800 by an operation pattern in which the power-off operation in which the 200 turns off the switch device 239 for a short time is repeated a predetermined number of times. There is an effect that can be done.

In addition, if the lighting state of the lamp is changed, the user can visually check if the brightness of the lamp is changed, but even if another lighting state is changed or the brightness of the lamp is changed, When the change width is small and there is a possibility that it is not possible to recognize that the lighting state of the lamp has been changed, the lighting control unit 173 generates a control signal that causes the lamp to blink. That is, the lighting control unit 173 generates the control signal “high output lighting” to light the lamp brightest, and immediately generates the control signal “low output lighting” to light the lamp darkest. After repeating this several times, return to the lighting state after the change. Thereby, the user can be surely notified that the lighting fixture 800 has changed the lighting state of the lamp.
Further, the lighting control unit 173 may blink the lamp instead of blinking the lamp. That is, the lighting control unit 173 repeatedly generated the control signal “high output lighting” to turn on the lamp, and immediately generated the control signal “off” to turn off the lamp. After that, return to the lighting state after the change.
However, when the lamp is a discharge lamp, blinking the discharge lamp shortens the life of the discharge lamp, so it is preferable to blink instead of blinking.

  The illumination control device 200 in this embodiment includes an operation input device 210 that inputs a user's operation, and an opening / closing pattern that is turned off for a predetermined time and then turned on based on the user's operation input by the operation input device 210. Since the switch device 230 repeats a predetermined number of times, when a user inputs a desired operation to the operation input device 210, a device such as the lighting fixture 800 connected to the AC power supply AC via the lighting control device 200 is provided. Can be controlled.

  The lighting control system 850 in this embodiment is connected to an AC power source AC through the lighting control device 200 and the switch device 230 of the lighting control device 200, and inputs an AC voltage from the AC power source AC. Therefore, the user can change the lighting state of the discharge lamp LA only by inputting a desired operation to the operation input device 210.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIGS.
Since the appearance of the lighting fixture 800 and the circuit configuration of the discharge lamp lighting device 100 in this embodiment are the same as those described in Embodiment 1, description thereof is omitted here.

In the first embodiment, when the lighting control device 200 opens and closes the switch device 230 in a predetermined pattern to input a command for changing the lighting state of the discharge lamp LA, and sequentially changes the lighting state of the discharge lamp LA. Explained.
In this embodiment, a description will be given of the discharge lamp lighting device 100 that prepares a plurality of operation patterns of the switch device 230 by the lighting control device 200 and inputs a command selected by a user from a plurality of types of commands.

FIG. 8 is a flowchart showing the flow of a change operation determination process in which the discharge lamp lighting device 100 according to this embodiment determines whether a change operation has been performed.
In addition, the same code | symbol is attached | subjected about the part which is common in the change operation determination process demonstrated in Embodiment 1, and description is abbreviate | omitted here.

In the interval determination step S633, the lighting control unit 173 compares the elapsed time when the measurement was started in the measurement start step S632 with the operation interval time, and determines whether or not the operation interval time has elapsed.
When it determines with operation interval time having passed, it progresses to frequency | count determination process S638.

In the number determination step S638, the lighting control unit 173 compares the number of repetitions of the power-off operation with the minimum number of off times. The minimum number of off times is the number of power off operations in an operation pattern with the smallest number of power off operations among a plurality of operation patterns.
When the power-off operation repeat count is less than the minimum off-count, the process returns to the operation acquisition step S631.
When the number of repetitions of the power-off operation is equal to or greater than the minimum number of off times, the process proceeds to the change determination step S639.

In the number determination step S635, the lighting control unit 173 compares the number of repetitions of the power-off operation with the maximum number of off times. The maximum number of off times is the number of power off operations in an operation pattern having the largest number of power off operations among a plurality of operation patterns.
If the number of power-off operations is less than the maximum number of off times, the process returns to the measurement start step S632.
If the number of repetitions of the power off operation is the maximum number of off times, the process proceeds to the change determination step S639.

  In the change determination step S639, the lighting control unit 173 determines that there has been a change operation corresponding to the number of times the power-off operation is repeated.

In this example, the plurality of operation patterns are distinguished by the number of repetitions of the power-off operation.
For example, when the power-off operation is repeated twice, a command to change the lighting state of the discharge lamp LA to the next lighting state (hereinafter referred to as “forward feeding change operation”) as described in the first embodiment. When the power-off operation is repeated four times, a command for directly changing the lighting state of the discharge lamp LA to a predetermined lighting state (for example, high output lighting or low output lighting) (hereinafter “ It is referred to as an “direct change operation”). The operation pattern that repeats the power-off operation three times is a margin for reliably distinguishing the two operation patterns. Therefore, if the operation pattern that repeats the power-off operation three times is entered as an undefined operation pattern It is treated as the same as when the power off operation is repeated twice.
As described above, when different types of operation patterns are distinguished based on the number of repetitions of the power-off operation, it is preferable that the number of repetitions in the plurality of types of operation patterns is separated in order to prevent erroneous determination due to instantaneous interruption or sag. For example, if the first operation pattern repeats the power-off operation 2 to 3 times, the second operation pattern desirably repeats the power-off operation 5 or more times. However, if the power-off operation is repeated too many times, it takes time to input a command to the discharge lamp lighting device 100. Therefore, it is desirable that the number is not more than 6 times at most.

  As a method for distinguishing a plurality of operation patterns, the operation patterns can be distinguished not only by the number of repetitions of the power-off operation but also by the length of the power-off period. For example, when the power off period of the second power off operation is longer than the first power off operation, and when the power off period of the second power off operation is shorter than the first power off operation. Differentiate and represent different commands.

FIG. 9 is a flowchart showing a flow of a lighting control process in which the discharge lamp lighting device 100 according to this embodiment controls the lighting and extinguishing of the discharge lamp LA.
In addition, the same code | symbol is attached | subjected about the part which is common in the lighting control process demonstrated in Embodiment 1, and description is abbreviate | omitted here.

In the change operation determination step S646, the lighting control unit 173 performs a change operation determination process.
When it is determined that the forward feed changing operation has been performed, the process proceeds to the medium output lighting step S647.
When it is determined that there has been a direct change operation, the change operation determination step S646 is repeated.

In the change operation determination step S648, the lighting control unit 173 performs a change operation determination process.
When it is determined that the forward feed changing operation has been performed, the process proceeds to the low output lighting step S649.
When it is determined that there has been a direct change operation, the process proceeds to the high output lighting step S645.

In the change operation determination step S650, the lighting control unit 173 performs a change operation determination process.
When it is determined that there has been a forward feed change operation or a direct change operation, the process proceeds to the high output lighting step S645.

As described above, by distinguishing a plurality of types of operation patterns, the discharge lamp lighting device 100 can change the lighting state of the discharge lamp LA based on a plurality of different commands.
Here, in order to simplify the explanation, the case where the lighting state of the discharge lamp LA is controlled in three stages has been described. However, when the lighting state of the discharge lamp LA can be changed more finely, the discharge lamp LA is moved forward. It may take time to change to the desired lighting state only by changing the lighting state of. Therefore, the number of operations required to obtain a desired lighting state can be reduced by incorporating a direct changing operation that directly changes the lighting state into a predetermined lighting state by a single changing operation.
Note that the plurality of commands are not limited to the two types of forward feed change operation and direct change operation, but may be two types of forward feed change operation and reverse feed change operation, for example, forward feed change operation and reverse feed change. There may be three types of operation and direct change operation.

  In the lighting device (discharge lamp lighting device 100) in this embodiment, the switch device 230 is opened and closed by a switch open / close signal generated by the operation pattern generation unit 271, so that a fine operation pattern such as the length of the power-off period is obtained. Can be easily distinguished. For this reason, since the lighting fixture 800 can distinguish many types of operation patterns and can change the lighting state of the discharge lamp LA, there are many such as a forward change operation, a reverse change operation, and a direct change operation corresponding to each lighting state. As a whole, the time required to input the operation pattern to the lighting fixture 800 can be shortened.

  In addition, since a command for the lighting fixture 800 is transmitted to the lighting fixture 800 through the power supply line, wiring for command transmission is not necessary.

Embodiment 3 FIG.
Embodiment 3 will be described with reference to FIG.

FIG. 10 is a block configuration diagram showing the overall configuration of the illumination control system 850 in this embodiment.
Note that portions common to the lighting fixture 800 described in Embodiment 1 are denoted by the same reference numerals, and description thereof is omitted here.

The lighting control system 850 includes a plurality of lighting fixtures 800. The plurality of lighting fixtures 800 are electrically connected in parallel to one AC power source AC, and the discharge lamps LA attached to the respective lighting fixtures 800 are simultaneously turned on or off by the operation of the power switch SW.
The discharge lamp lighting device 100 includes a discharge lamp detection circuit 190. The discharge lamp detection circuit 190 detects whether or not the discharge lamp LA is connected to the lamp socket 810, and generates and outputs a discharge lamp detection signal representing the detected result.

  The lighting control unit 173 receives the discharge lamp detection signal generated by the discharge lamp detection circuit 190, and determines that the discharge lamp LA is connected to the lamp socket 810 based on the detection result represented by the input discharge lamp detection signal. And when it determines with having changed operation, the lighting state of the discharge lamp LA is changed. Even when it is determined that the change operation has been performed, the lighting control unit 173 does not change the lighting state of the discharge lamp LA when it is determined that the discharge lamp LA is not connected to the lamp socket 810.

Thus, in the lighting control system 850 in which a plurality of lighting fixtures 800 are connected to one power switch SW, the discharge lamp lighting device 100 operates the power switch SW when the discharge lamp LA is connected. Based on the above, the lighting state of the discharge lamp LA is changed, and when the discharge lamp LA is not connected, the lighting state of the discharge lamp LA is not changed.
Therefore, after the user removes the discharge lamp LA that the user does not want to change the lighting state, the lighting controller 200 is operated to input a command to the lighting fixture 800, whereby the lighting state of the discharge lamp LA that the lighting state is desired to be changed. Can only change.

  Even when the discharge lamp LA is not connected to the lamp socket 810, the lighting control unit 173 may be configured to change the lighting state of the discharge lamp LA. When the discharge lamp LA is not connected, the lighting control unit 173 generates a control signal “extinguish” in order to protect the circuit. Therefore, the lighting control unit 173 only changes the lighting state of the discharge lamp LA stored in the state storage unit 181.

  Alternatively, when the lighting control unit 173 detects that the discharge lamp LA is not connected for a predetermined time or more based on the discharge lamp detection signal generated by the discharge lamp detection circuit 190, the lighting state of the discharge lamp LA is predetermined. It is good also as a structure which returns to the initial state (for example, high output lighting).

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIG.

FIG. 11 is a block configuration diagram showing the overall configuration of the illumination control system 850 in this embodiment.
Note that a description of portions common to the illumination control system 850 described in Embodiment 1 is omitted here.

The lighting control system 850 further does not include the lighting control device 200.
In the lighting control system 850 in this embodiment, when the user turns on / off the power switch SW, an operation pattern similar to the opening / closing pattern of the switch device 230 generated by the lighting control device 200 in Embodiment 1 is generated, The discharge lamp lighting device 100 changes the lighting state such as the brightness of the discharge lamp LA based on the operation of the power switch SW by the user.

When an operation pattern is generated by a user's manual operation, the power switch SW cannot be turned on and off so quickly, so the length of the off period is set to about 0.5 seconds to several seconds. For this reason, it is necessary to set the maximum off period to about several seconds, and the lighting continuation possible time t is set to a value longer than that.
For example, if the capacitance value C of the smoothing capacitor C24 is increased, the lighting continuation possible time t can be lengthened. Further, when the secondary battery is built in, the discharge lamp LA can be lit by the voltage charged in the secondary battery even if the capacitance value C of the smoothing capacitor C24 is small. can do.

  In this case, it is preferable that the maximum off period is about several seconds even if the lighting continuation possible time t is, for example, several tens of seconds to several minutes. As described above, even if the user turns off the power switch SW in an attempt to turn off the discharge lamp LA, it cannot be distinguished from the change operation for changing the lighting state until the maximum off period has elapsed. This is because the turn-off of the discharge lamp LA is delayed.

FIG. 3 is a perspective view illustrating an appearance of a lighting fixture 800 according to Embodiment 1. FIG. 2 is a block configuration diagram showing an overall configuration of a lighting control system 850 in the first embodiment. FIG. 3 is a flowchart showing a flow of operation determination processing in which the discharge lamp lighting device 100 according to Embodiment 1 determines the operation content. The discharge lamp lighting device 100 in Embodiment 1 shows the flowchart which shows the flow of the change operation determination process which determines whether there was change operation. The flowchart figure which shows the flow of the lighting control process in which the discharge lamp lighting device 100 in Embodiment 1 controls lighting / extinguishing of the discharge lamp LA. FIG. 3 is a timing chart illustrating an example of an operation in which the discharge lamp lighting device 100 according to Embodiment 1 determines the operation content. FIG. 3 is a timing chart illustrating an example of an operation in which the discharge lamp lighting device 100 according to Embodiment 1 controls the lighting state of the discharge lamp LA according to a user operation. The discharge lamp lighting device 100 in Embodiment 2 is a flowchart showing the flow of change operation determination processing for determining whether or not there has been a change operation. The flowchart figure which shows the flow of the lighting control process which the discharge lamp lighting device 100 in Embodiment 2 controls lighting / extinguishing of the discharge lamp LA. FIG. 10 is a block configuration diagram showing an overall configuration of a lighting control system 850 in a third embodiment. FIG. 10 is a block configuration diagram showing an overall configuration of a lighting control system 850 in a fourth embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 Discharge lamp lighting device, 110 DC power supply circuit, 130 Inverter circuit, 135 Drive circuit, 150,250 Control power supply circuit, 160 Power supply detection circuit, 170,270 Microcomputer, 171 Off period measurement part, 172 Off operation determination part, 173 Control unit, 180 non-volatile memory, 181 state storage unit, 190 discharge lamp detection circuit, 200 lighting control device, 210 operation input device, 230 switch device, 271 operation pattern generation unit, 800 lighting fixture, 810 lamp socket, 850 lighting control System, AC AC power supply, C24 smoothing capacitor, C42, C43 capacitor, D23 diode, DB diode bridge, L21, L41 coil, LA discharge lamp, PFC boost control circuit, Q22, Q31, Q32 switching element, S W Power switch.

Claims (7)

A DC power supply circuit that inputs AC voltage and generates DC voltage from the input AC voltage;
A smoothing capacitor charged by a DC voltage generated by the DC power supply circuit;
A power supply detection circuit for detecting whether or not the DC power supply circuit is inputting an AC voltage;
Based on the detection result detected by the power supply detection circuit, when the DC power supply circuit does not input an AC voltage and then the DC power supply circuit inputs an AC voltage, the DC power supply circuit inputs an AC voltage. An off-period measurement unit that measures the length of the period that did not exist,
When the length of the period measured by the off period measurement unit is within a predetermined range, an off operation determination unit that determines that there has been one power off operation,
A lighting control unit that generates a control signal for changing the lighting state of the lamp when it is determined that a predetermined number of power-off operations have been performed within a predetermined period based on the determination result determined by the off operation determination unit. When,
A lighting device comprising: a lighting circuit that generates electric power to be supplied to the lamp from a DC voltage charged in the smoothing capacitor based on a control signal generated by the lighting control unit.   The off-operation determining unit is configured such that the upper limit of the predetermined range for determining the power-off operation is greater than the time until the voltage charged in the smoothing capacitor is discharged by the operation of the lighting circuit and becomes the predetermined voltage. The lighting device according to claim 1, wherein the lighting device is a short time. 3. The off operation determination unit according to claim 1, wherein an upper limit of the predetermined range for determining the power off operation is a time shorter than a time t calculated by the equation (1). Lighting device.

Where C is the capacitance value of the smoothing capacitor. _VDC is a voltage value of a DC voltage generated by the DC power supply circuit. W _OUT is the maximum power consumption value of the lamp. e is the base of the natural logarithm. V _MIN is the minimum voltage value that can maintain the lighting of the lamp among the voltages input by the lighting circuit. The lighting device has a state storage unit that stores the lighting state of the lamp changed by the lighting control unit,
Based on the detection result detected by the power supply detection circuit, the lighting control unit stores the lighting state of the lamp when the DC power supply circuit starts to input AC voltage after the lamp is turned off. The lighting device according to any one of claims 1 to 3, wherein a control signal for making the lighting state stored by the unit is generated.   5. A lighting apparatus comprising: the lighting device according to claim 1; and a lamp connecting portion that connects the lamp. An operation input device for inputting a user's operation;
An illumination control device comprising: a switch device that repeats a predetermined number of times an opening / closing pattern that is turned off for a predetermined time and then turned on based on a user operation input by the operation input device. The lighting control device according to claim 6;
A lighting control system comprising: the lighting fixture according to claim 5, wherein the lighting fixture is connected to an AC power source via a switch device of the lighting control device and receives an AC voltage from the AC power source.

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