JP6300303B2 - Light source lighting device, light source lighting method, and electronic apparatus - Google Patents

Description

  The present invention relates to a light source lighting device and a light source lighting method for lighting a light emitting element such as an LD (Laser Diode) or an LED (Light Emitting Diode). Moreover, this invention relates to the electronic device provided with such a light source lighting device.

  FIG. 6 shows an example of a light source lighting device. As shown in FIG. 6, the light source lighting device includes a power source 1, a DC / DC converter unit 2, and a light source driving unit 3.

  The power source 1 is a circuit that generates DC power from AC power. For example, a rectifier circuit that full-wave rectifies AC power and outputs DC power, and a PFC (Power Factor Correction) that uses the output of the rectifier circuit as input. ) Circuit.

  The PFC circuit is a circuit that corrects the power factor, and includes, for example, a diode, a switching element, a smoothing capacitor, and the like. The output voltage of the PFC circuit is supplied to the DC / DC converter unit 2.

  The DC / DC converter unit 2 includes a converter circuit 2a that converts the output voltage of the PFC circuit into a predetermined voltage. The output voltage of the converter circuit 2a is supplied to the light source drive unit 3 as the input voltage Vin.

  The light source driving unit 3 turns on the light source by constant current driving, and includes a converter circuit 3a that operates by receiving the voltage output from the converter circuit 2a. A plurality of light emitting elements 4 as light sources are connected in series to the output line of the converter circuit 3a.

  The converter circuit 3a receives a lighting signal S1 and a drive current variable signal S2 from a CPU (Central Processing Unit) unit 5 of the apparatus main body on which the light source lighting device and the light source are mounted. The converter circuit 3a performs current control so that the drive current amount indicated by the drive current variable signal S2 flows to each light emitting element 4 when the lighting signal S1 is in the ON state. At this time, the output voltage Vout of the converter circuit 3 a is the sum of the operation forward voltages Vf of the light emitting elements 4.

  Next, the light source lighting operation by the light source lighting device will be briefly described.

  When the power source 1 and the DC / DC converter unit 2 are in the operating state and the lighting signal S1 output from the CPU unit 5 is in the OFF state, the converter circuit 3a does not supply a driving current to the light source. This state corresponds to, for example, a state when the apparatus main body is in the standby mode.

  When the power source 1 and the DC / DC converter unit 2 are in the operating state, the lighting signal S1 output from the CPU unit 5 is in the ON state, and the drive current variable signal S2 is supplied to the converter circuit 3a, the converter circuit 3a performs current control so that the amount of current flowing through each light emitting element 4 becomes the amount of drive current indicated by the drive current variable signal S2. Thereby, each light emitting element 4 of a light source lights.

  When changing the illuminance of the light source, the CPU unit 5 supplies the converter circuit 3a with a drive current variable signal S2 indicating a drive current amount corresponding to the changed illuminance in response to an input operation for changing the illuminance by the user. To do. The converter circuit 3a performs current control so that the amount of current flowing through each light emitting element 4 becomes the changed amount of drive current indicated by the drive current variable signal S2.

  In the above-described light source lighting device, the input voltage Vin (output voltage of the converter circuit 2a) of the light source drive unit 3 is based on the following formula 1 so that a predetermined amount of drive current can be reliably supplied to the light emitting element 4. Is set.

  In the above formula 1, Vf (max) indicates the maximum operating forward voltage of the light emitting element 4, and n (a natural number of 1 or more) indicates the number of the light emitting elements 4. ΔV1 is an assumed value of the input / output potential difference of the light source driving unit 3, and is usually set to a value that is necessary for the operation of the light source driving unit 3 and has the highest conversion efficiency.

  The maximum operation forward voltage Vf (max) is set in consideration of initial variation and characteristics (for example, temperature characteristics and life characteristics) of the light emitting element 4, a margin with respect to the actual value, and the like.

  The initial variation is an individual difference in the operation forward voltage Vf of the light emitting element 4.

  The temperature characteristic generally indicates that the operation forward voltage Vf increases as the temperature decreases, and the operation forward voltage Vf decreases as the temperature increases. According to this temperature characteristic, when a drive current starts to flow through the light emitting element 4, the temperature of the light emitting element 4 increases, and the operation forward voltage Vf decreases accordingly.

  Due to the secular change of the light emitting element 4, the operation forward voltage Vf tends to gradually increase, and such characteristics are called life characteristics.

  The maximum operation forward voltage Vf (max) is a voltage that ensures a voltage margin that can be reliably driven in addition to the variation in the operation forward voltage Vf due to the individual difference and the fluctuation of the operation forward voltage Vf due to the temperature characteristic and the life characteristic.

  A predetermined amount of driving current can be reliably supplied to the light emitting element 4 by setting the input voltage Vin so that the light emitting element 4 can be operated even at the maximum operating forward voltage Vf (max) according to the above formula 1.

  FIG. 7 shows a time chart of the light source driving operation of the light source lighting device shown in FIG.

  Referring to FIG. 7, the input voltage Vin of the converter circuit 3a of the light source driving unit 3 is fixed to a voltage [Vf (max) × n + ΔV1].

  At time T1, the lighting signal S1 is turned on, and the set value A1 is set as the drive current variable signal S2. The converter circuit 3a performs current control so that the amount of current supplied to each light emitting element 4 becomes the amount of drive current indicated by the set value A1. Thereby, each light emitting element 4 lights up.

  After lighting, the temperature of each light emitting element 4 gradually increases, and the operation forward voltage Vf decreases accordingly. As the operating forward voltage Vf decreases, the output voltage Vout of the converter circuit 3a decreases.

  After the time T2, the operating state of each light emitting element 4 is stabilized, and the temperature of each light emitting element 4 and the output voltage Vout of the converter circuit 3a become substantially constant.

  When the set value of the drive current variable signal S2 is switched from A1 to A2 (<A1) at time T3, the converter circuit 3a sets the amount of current supplied to each light emitting element 4 to the drive current amount indicated by the set value A2. Current control is performed so that Thereby, the amount of current supplied to each light emitting element 4 decreases from the amount of drive current indicated by the set value A1 to the amount of drive current indicated by the set value A2.

  When the amount of current supplied to each light emitting element 4 decreases, the temperature of each light emitting element 4 gradually decreases, and the operation forward voltage Vf increases accordingly. As the operation forward voltage Vf increases, the output voltage Vout of the converter circuit 3a increases.

  After time T4, the operation state of each light emitting element 4 is stabilized, and the temperature of each light emitting element 4 and the output voltage Vout of the converter circuit 3a become substantially constant.

  As another example of the light source lighting device, Patent Literature 1 describes an LED lighting device.

  The LED lighting device described in Patent Document 1 includes a first buck converter, a second buck converter, and control means.

  The first buck converter steps down the input voltage to the first voltage. The second buck converter steps down the first voltage, which is the output of the first buck converter, to the second voltage and supplies it to the LED.

  Each of the first buck converter and the second buck converter includes a switching unit. By increasing or decreasing the duty ratio of these switching units, the current and voltage supplied to the LED can be adjusted.

  A resistance element for detecting voltage is inserted in the output line of the second buck converter. The control means detects the voltage generated at both ends of the resistance element, and controls the operations of the switching units of both the first buck converter and the second buck converter based on the detection result.

  Specifically, the control means increases the duty ratio of both switching units when the detection voltage decreases, and decreases the duty ratio of both switching units when the detection voltage increases. Thereby, the voltage (voltage supplied to the LED) generated in the resistance element can be maintained at a predetermined voltage.

International Publication WO2012 / 144274

  In general, the conversion efficiency of the light source driver 3 is determined by the ratio of the output voltage Vout to the input voltage Vin. Therefore, the smaller the input / output potential difference ΔV, which is the difference between the input voltage Vin and the output voltage Vout, the higher the conversion efficiency. The output voltage Vout is the sum of the operation forward voltages Vf of the light emitting element 4. However, if the input voltage Vin is set higher than the output voltage Vout, the input / output potential difference ΔV increases, and the conversion of the light source driving unit 3 is performed. Efficiency is reduced. When the conversion efficiency of the light source driving unit 3 decreases, problems such as a temperature rise of the light source driving unit 3 and an increase in power consumption occur.

  In the light source lighting device shown in FIG. 6, the input voltage Vin is fixed at [Vf (max) × n + ΔV1] so that the light emitting element 4 can operate even at the maximum operating forward voltage Vf (max). In this case, since the input voltage Vin becomes very large with respect to the output voltage Vout, the input / output potential difference ΔV becomes large, and the conversion efficiency of the light source driving unit 3 decreases.

  For example, if the forward voltage in the lighting operation state of the light emitting element 4 is Vf (op), the relationship is Vf (max)> Vf (op), and the input voltage Vin is [Vf (max) with respect to the output voltage Vout. ) −Vf (op)] × n. As a result, the input / output potential difference ΔV is large, the conversion efficiency of the light source driving unit 3 is lowered, and the above problems of temperature rise and power consumption increase occur.

  In the LED lighting device described in Patent Document 1, the voltage (that is, voltage Vout) generated in the resistance element is maintained at a predetermined voltage. In this case, for example, when the operation forward voltage Vf of the LED fluctuates due to temperature characteristics or the like, a predetermined amount of drive current cannot be supplied to the LED, and the LED may not light up.

  It should be noted that the LED can be reliably turned on by setting a predetermined voltage so that the LED can be operated even at the maximum operation forward voltage Vf (max). The input / output potential difference ΔV of the conversion unit composed of the converter is increased, the conversion efficiency of the conversion unit is reduced, and the above problems of temperature rise and power consumption increase occur.

  The objective of this invention is providing the light source lighting device and the light source lighting method which can improve the conversion efficiency of a light source drive part.

  Another object of the present invention is to provide an electronic apparatus equipped with such a light source lighting device.

In order to achieve the above object, according to one aspect of the present invention,
A light source lighting device for lighting a light emitting element,
A converter for converting an input voltage into a first voltage;
The light emitting element receives the first voltage output from the converter unit and a control signal indicating a driving current value of the light emitting element and inputs a driving current having a value indicated by the control signal to the light emitting element. A light source driving unit that changes an output voltage applied to
The converter unit fixes the first voltage to a predetermined voltage at the start of lighting of the light emitting element, and after lighting, the difference between the input voltage and the output voltage of the light source driving unit becomes a predetermined value. A light source lighting device for adjusting the first voltage is provided.

According to another aspect of the present invention,
A light source lighting method performed in an apparatus including a light source driving unit that receives a first voltage and changes an output voltage applied to the light emitting element so that a predetermined amount of driving current flows to the light emitting element,
The first voltage is fixed to a predetermined voltage at the start of lighting of the light emitting element, and the first voltage is set so that a difference between an input voltage and an output voltage of the light source driving unit becomes a predetermined value after lighting. A light source lighting method for adjusting the voltage of the light source is provided.

In order to achieve the other object, according to one aspect of the present invention,
A light emitting element;
A light source lighting device for lighting the light emitting element;
A control unit for controlling a lighting operation of the light source lighting device and supplying a control signal indicating a driving current value of the light emitting element to the light source lighting device;
The light source lighting device is:
A converter for converting an input voltage into a first voltage;
A light source driving unit that receives the first voltage output from the converter unit and changes an output voltage applied to the light emitting element so that a driving current having a value indicated by the control signal flows to the light emitting element; Have
The converter unit fixes the first voltage to a predetermined voltage at the start of lighting of the light emitting element, and after lighting, the difference between the input voltage and the output voltage of the light source driving unit becomes a predetermined value. An electronic device for adjusting the first voltage is provided.

  According to the present invention, the conversion efficiency of the light source driving unit can be improved.

It is a block diagram which shows the structure of the light source lighting device which is the 1st Embodiment of this invention. It is a figure for demonstrating the light source drive operation | movement of the light source lighting device shown in FIG. It is a block diagram which shows the structure of the light source lighting device which is the 2nd Embodiment of this invention. It is a block diagram which shows the structure of the light source lighting device which is the 3rd Embodiment of this invention. It is a block diagram which shows the structure of the electronic device of this invention. It is a block diagram which shows an example of the light source lighting device which is a related technique of this invention. It is a figure for demonstrating the light source drive operation | movement of the light source lighting device shown in FIG.

  Next, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a configuration of a light source lighting device according to the first embodiment of the present invention.

  Referring to FIG. 1, the light source lighting device lights a light source composed of a light emitting element such as an LD or an LED, and includes a power source 1, a DC / DC converter unit 2, and a light source driving unit 3. The power supply 1 has the same configuration as that shown in FIG.

  The DC / DC converter unit 2 and the light source driving unit 3 are partially different from those shown in FIG.

  The DC / DC converter unit 2 converts the output voltage of the PFC circuit of the power supply 1 into a first voltage. The DC / DC converter unit 2 outputs a predetermined voltage [Vf (max) × n + ΔV1] as the first voltage at the start of lighting of the light source, and after lighting (for example, a predetermined time elapses from the lighting start time) After that, the first voltage is adjusted so that the difference between the output voltage of the light source driving unit 3 and the input voltage (input / output potential difference) becomes a predetermined value.

  The light source drive unit 3 turns on the light source by constant current drive, and operates by being supplied with the first voltage from the DC / DC converter unit 2, and supplies current to the light source in response to a lighting start instruction. While supplying and lighting, current control is performed so that the drive current flowing through the light source becomes a predetermined amount.

  Below, the structure of the DC / DC converter part 2 and the light source drive part 3 is demonstrated concretely.

  The DC / DC converter unit 2 includes a converter circuit 2 a and an output voltage control circuit 6. The light source driving unit 3 includes a converter circuit 3 a and an output voltage detection circuit 7. A plurality of light emitting elements 4 as light sources are connected in series to the output of the light source driving unit 3. The light emitting element 4 is a solid light source such as an LD or an LED.

  The converter circuit 2a converts the output voltage of the PFC circuit of the power source 1 into a first voltage. The first voltage is supplied to the converter circuit 3a as the input voltage Vin.

  The converter circuit 3a is the same as that shown in FIG. 6, operates by receiving the first voltage output from the DC / DC converter unit 2, and a predetermined amount of driving current is applied to each light emitting element 4. Constant current drive is performed so that it flows. The lighting signal 1 and the drive current variable signal S2 are supplied from the CPU unit 5 of the apparatus main body to the converter circuit 3a.

  The output voltage detection circuit 7 monitors the second voltage (output voltage Vout) output from the converter circuit 3 a and supplies an output voltage detection signal P indicating the monitoring result (detection voltage) to the output voltage control circuit 6. . For example, the output voltage detection circuit 7 may detect the output voltage Vout at regular time intervals and supply an output voltage detection signal P indicating the detection result to the output voltage control circuit 6.

  The output voltage control circuit 6 receives an ON / OFF signal (startup control signal) S3 indicating start / stop from the CPU unit 5 of the apparatus main body. When the ON / OFF signal S3 is in the ON state, the output voltage control circuit 6 adjusts the output voltage of the DC / DC converter unit 2 (the input voltage Vin of the light source driving unit 3) based on the output voltage detection signal P. When the ON / OFF signal S3 is in the OFF state, the output voltage control by the output voltage control circuit 6 is not performed.

  The configuration of the output voltage control circuit 6 will be described below. However, the following first and second configurations are examples, and other configurations (an output voltage control circuit in an existing booster circuit or a step-down circuit) may be applied to the output voltage control circuit 6.

(First Configuration of Output Voltage Control Circuit 6)
Based on the output voltage detection signal P, the output voltage control circuit 6 controls the step-up or step-down operation of the converter circuit 2a. Specifically, the output voltage control circuit 6 uses the voltage [Vout + ΔV1] obtained by adding the estimated value ΔV1 of the input / output potential difference of the converter circuit 3a to the detection voltage indicated by the output voltage detection signal P as the first voltage. You may make it output more.

  In the above configuration, for example, when the converter circuit 2a is configured by a switching unit (for example, a switching regulator unit) that can adjust the output voltage by increasing or decreasing the duty ratio, the output voltage control circuit 6 includes the first The duty ratio of the switching unit may be increased / decreased so that the voltage [Vout + ΔV1] is output as the above voltage.

  In the above case, the output voltage control circuit unit 6 includes a comparison circuit (differential amplifier) that detects a difference voltage between the output voltage of the converter circuit 2a and the detection voltage of the output voltage Vout of the converter circuit 3a, and the ON / OFF signal S3. And a voltage control unit that adjusts the duty ratio of the converter circuit 2a so that the differential voltage becomes a predetermined value (ΔV1) when is ON.

(Second configuration of output voltage control circuit 6)
The output voltage control circuit 6 generates a voltage [Vout + ΔV1] based on the output voltage detection signal P when the ON / OFF signal S3 is in the ON state.

  In the above case, the output voltage control circuit unit 6 outputs a voltage [Vout + ΔV1] obtained by adding the input / output potential difference ΔV1 to the detection voltage of the output voltage Vout of the light source driving unit 3, and the output voltage of the converter circuit 2a. A first input terminal to be supplied, a second input terminal to which the output voltage of the voltage generator is supplied, and an output terminal; when the ON / OFF signal S3 is in the OFF state, the first input terminal Switch means for outputting the voltage input to the second input terminal from the output terminal in the ON state.

  Next, the operation of the light source lighting device of this embodiment will be described.

  FIG. 2 shows a time chart of the light source driving operation. The operation will be described below with reference to FIGS.

  The power source 1, the DC / DC converter unit 2, and the light source driving unit 3 are in an operating state, and the lighting signal S1 and the ON / OFF signal S3 are all in an OFF state. In this state, the DC / DC converter unit 2 outputs the voltage [Vf (max) × n + ΔV1] as the first voltage, but the converter circuit 3a does not supply current to the light emitting element.

  At time T1, the lighting signal S1 is turned on, and the drive current variable signal S2 indicating the set value A1 is supplied to the converter circuit 3a. The DC / DC converter unit 2 supplies the voltage [Vf (max) × n + ΔV1] as the first voltage to the converter circuit 3a. The converter circuit 3a operates in response to the voltage [Vf (max) × n + ΔV1], and performs current control so that the amount of current supplied to each light emitting element 4 becomes the amount of drive current indicated by the set value A1. Thereby, each light emitting element 4 lights up.

  During the period from time T1 to time T3, since the lighting signal S1 is in the ON state and the ON / OFF signal S3 is in the OFF state, the input voltage Vin of the light source driving unit 3 is fixed to the voltage [Vf (max) × n + ΔV1]. Has been. The converter circuit 3a operates by receiving the voltage [Vf (max) × n + ΔV1] and continues the current control (constant current drive).

  After lighting, the temperature of each light emitting element 4 gradually increases, and the operation forward voltage Vf decreases accordingly. When the operation forward voltage Vf decreases, the output voltage Vout of the converter circuit 3a decreases as the operation forward voltage Vf decreases.

  At time T2, the operating state of each light emitting element 4 is stabilized, and after time T2, the temperature of each light emitting element 4 and the output voltage Vout of the converter circuit 3a become substantially constant.

  When the ON / OFF signal S3 is turned on at time T3, the output voltage control circuit 6 outputs the output voltage of the DC / DC converter unit 2 (the input voltage Vin of the light source driving unit 3) based on the output voltage detection signal P. Adjust. Specifically, the output voltage control circuit 6 causes the DC / DC converter unit 2 to output, as a first voltage, a voltage [Vout + ΔV1] obtained by adding the input / output potential difference ΔV1 to the detected voltage. The converter circuit 3a operates in response to the voltage [Vout + ΔV1] and continues the current control (constant current drive).

  Since the lighting signal S1 and the ON / OFF signal S3 are both ON during the period from the time T3 to the time T4, the DC / DC converter unit 2 outputs the voltage [Vout + ΔV1] by the voltage control of the output voltage control circuit 6. To do. The converter circuit 3a operates in response to the voltage [Vout + ΔV1] and continues the current control (constant current drive).

  At time T4, the set value of the drive current variable signal S2 is switched from A1 to A2 (<A1), and at the same time, the ON / OFF signal S3 is turned off.

  During the period from time T4 to time T5, since the lighting signal S1 is in the ON state and the ON / OFF signal S3 is in the OFF state, voltage control by the output voltage control circuit 6 is not performed. For this reason, the input voltage Vin of the light source driving unit 3 is fixed to the voltage [Vf (max) × n + ΔV1]. The converter circuit 3a operates in response to the voltage [Vf (max) × n + ΔV1] and performs current control so that the amount of current supplied to each light emitting element 4 becomes the amount of drive current indicated by the set value A2. Thereby, the amount of current supplied to each light emitting element 4 decreases from the amount of drive current indicated by the set value A1 to the amount of drive current indicated by the set value A2.

  When the amount of current supplied to each light emitting element 4 decreases, the temperature of each light emitting element 4 gradually decreases, and the operation forward voltage Vf increases accordingly. When the operation forward voltage Vf increases, the output voltage Vout of the converter circuit 3a increases as the operation forward voltage Vf increases. Thereafter, the operation state of each light emitting element 4 is stabilized, and the temperature of each light emitting element 4 and the output voltage Vout of the converter circuit 3a become substantially constant.

  When the ON / OFF signal S3 is turned on at time T5, the output voltage control circuit 6 causes the output voltage of the DC / DC converter unit 2 (the input voltage Vin of the light source driving unit 3) based on the output voltage detection signal P. Adjust. Specifically, the output voltage control circuit 6 causes the DC / DC converter unit 2 to output, as a first voltage, a voltage [Vout + ΔV1] obtained by adding the input / output potential difference ΔV1 to the detected voltage. The converter circuit 3a operates in response to the voltage [Vout + ΔV1] and continues the current control (constant current drive).

  Examples of scenes where the drive current is increased or decreased by the drive current variable signal S2 include, for example, when adjusting the contrast, when changing the illuminance according to the brightness around the apparatus body, when reducing the power consumption of the apparatus body, There are times when you want to extend your life. When the drive current is increased at the time of continuous lighting, the forward operation voltage Vf decreases, so that the operation during the period of time T3 to T4 is continued.

  The light source driving operation described above provides the following operational effects.

  At the start of lighting (period T1 to T3) or when the illuminance is changed (period T4 to T5), the input voltage of the light source driver 3 is set so that the light emitting element 4 can operate even at the maximum operating forward voltage Vf (max). Vin is set to [Vf (max) × n + ΔV1]. Thereby, the light emitting element 4 can be driven reliably.

  For example, in order to reliably drive the drive current to the light emitting element 4 at room temperature or low temperature, it is necessary to operate the light emitting element 4 at the maximum operation forward voltage Vf (max). By setting the input voltage Vin to [Vf (max) × n + ΔV1], the light emitting element 4 can be reliably driven even in such an operating environment.

  After a predetermined time elapses after the light emitting element 4 is turned on or after the illuminance of the light emitting element 4 is changed, voltage control is performed by the output voltage control circuit 6, and the input / output potential difference ΔV1 is set to the output voltage of the converter circuit 3a. The added voltage [Vout + ΔV1] is supplied to the converter circuit 3a as the input voltage Vin. The value [Vout + ΔV1] of the input voltage Vin is smaller than the value [Vf (max) × n + ΔV1] of the input voltage Vin.

  For example, if the forward voltage when the light-emitting element 4 is in the lighting operation state is Vf (op), the relationship is Vf (max)> Vf (op), and the value of [Vout + ΔV1] is [Vf (max) × n + ΔV1]. [Vf (max) −Vf (op)] × n. Thus, since the input / output potential difference ΔV of the light source driving unit 3 can be reduced, the conversion efficiency of the light source driving unit 3 can be increased.

  If the operation forward voltage Vf of the light emitting element 4 varies during voltage control by the output voltage control circuit 6, the output voltage Vout of the converter circuit 3a also varies with the variation of the operation forward voltage Vf. In the present embodiment, the output voltage Vout is monitored at regular time intervals, and the input voltage Vin is set according to the detected voltage. Therefore, the output voltage Vout is not affected by such fluctuations in the operation forward voltage Vf, and the light source The drive unit 3 can be operated with maximum efficiency.

  As described above, according to the light source lighting device of the present embodiment, the output voltage Vout of the light source driving unit 3 is monitored, and the output voltage of the DC / DC converter unit 2 (the light source driving unit 3 is based on the output voltage detection signal P). By controlling the input voltage Vin), the light source drive unit 3 can be operated with maximum efficiency while reliably supplying a predetermined amount of drive current to the light emitting element 4. Thereby, the temperature rise of the light source drive part 3 can be suppressed, the loss of the light source drive part 3 can be suppressed low, and power consumption can be reduced.

  In the operation shown in FIG. 2, voltage control by the output voltage control circuit 6 is performed after a predetermined time has elapsed after the light emitting element 4 is turned on or after the illuminance change of the light emitting element 4 is changed. This is due to the following reasons.

  In the operation example shown in FIG. 7 (in which the input voltage Vin is fixed to the voltage [Vf (max) + ΔV1]), the operation forward voltage Vf of the light emitting element 4 during the period of time T1 to T2 and the period of time T3 to T4. Since the output voltage Vout also fluctuates, the input / output potential difference ΔV of the light source driving unit 3 may not be so large depending on the fluctuation state of the output voltage Vout. For this reason, even if the voltage control by the output voltage control circuit 6 is applied, the conversion efficiency improvement effect of the light source driving unit 3 may not be obtained so much depending on the fluctuation state of the output voltage Vout.

  On the other hand, since the lighting operation state of the light emitting element 4 is stable during the period of time T2 to T3 and after the time T4, the operation forward voltage Vf and the output voltage Vout of the light emitting element 4 are constant. The input / output potential difference ΔV always maintains a large value. For this reason, if the voltage control by the output voltage control circuit 6 is applied, a very large effect can be obtained with respect to improving the conversion efficiency of the light source driving unit 3.

  From the above, in order to effectively improve the conversion efficiency of the light source driving unit 3, it is desirable to perform it during a period in which the lighting operation state of the light emitting element 4 is stable. From this point of view, in the present embodiment, the voltage control by the output voltage control circuit 6 is performed after a predetermined time has elapsed after the light emitting element 4 is turned on or after the illuminance change of the light emitting element 4 is changed.

  The voltage control by the output voltage control circuit 6 may be executed at an arbitrary timing after the light emitting element 4 is turned on or after the illuminance change of the light emitting element 4 is changed. For example, the voltage control by the output voltage control circuit 6 may be started immediately after the light emitting element 4 is turned on or immediately after the illuminance change of the light emitting element 4 is changed.

  Further, when the illuminance of the light emitting element 4 is changed, the input voltage Vin is set to [Vf (max) × n + ΔV1], but this setting may be omitted. That is, after setting the input voltage Vin to [Vf (max) × n + ΔV1] to light the light emitting element 4 and starting the voltage control by the output voltage control circuit 6, even if the illuminance is changed, the output voltage control is performed as it is. The voltage control by the circuit 6 may be continued.

  In the light source lighting device of the present embodiment, the set value of the drive current indicated by the drive current variable signal S2 is not limited to two, A1 and A2. The set value may be indicated from among three or more set values by the drive current variable signal S2.

  In addition, the light source to be turned on by the light source driving unit 3 is a plurality of light emitting elements 4 connected in series, but is not limited thereto. The number of light emitting elements 4 constituting the light source may be one. However, the more light emitting elements 4 connected in series, the greater the effect of improving the efficiency of the light source driving unit 3.

  In addition, the light source driving device of the present embodiment can be applied to a light source in which a plurality of light emitting elements 4 are connected in parallel. In that case, the effect of improving the conversion efficiency of the light source driving unit 3 is small.

(Second Embodiment)
FIG. 3 is a block diagram showing a configuration of a light source lighting device according to the second embodiment of the present invention.

  The light source lighting device of this embodiment differs from that of the first embodiment in that a timer circuit 8 is added to the DC / DC converter unit 2 without using the ON / OFF signal S3.

  The timer circuit 8 measures the elapsed time from the lighting start time or the illuminance change time. The lighting signal S1 and the drive current variable signal S2 are supplied to the converter circuit 3a and the output voltage control circuit 6.

  The output voltage control circuit 6 includes first time information indicating a time from when the lighting is disclosed until the state of the light emitting element 4 is stabilized (time corresponding to the period of time T1 to T3 illustrated in FIG. 2), and illuminance change. Second time information indicating the time from the time point until the state of the light emitting element 4 is stabilized (time corresponding to the period of time T4 to T5 shown in FIG. 2) is held in advance.

  The output voltage control circuit 6 determines the lighting start time based on the lighting signal S1, and causes the timer circuit 8 to measure the elapsed time from the lighting start time. Then, when the measurement time of the timer circuit 8 reaches the time indicated by the first time information, the output voltage control circuit 6 determines that the lighting operation state of the light emitting element 4 is stable. Thereby, the output voltage control circuit 6 can recognize the period of time T1-T3 shown in FIG.

  The output voltage control circuit 6 determines the illuminance change time based on the drive current variable signal S2, and causes the timer circuit 8 to measure the elapsed time from the illuminance change time. Then, the output voltage control circuit 6 determines that the lighting operation state of the light emitting element 4 is stable when the measurement time of the timer circuit 8 reaches the time indicated by the second time information. Thereby, the output voltage control circuit 6 can recognize the period of time T4 to T5 shown in FIG.

  Since operations other than the period determination using the timer circuit 8 are the same as those in the first embodiment, the description thereof is omitted here.

  The light source lighting device of the present embodiment also has the same effects as those of the first embodiment.

  Moreover, all the variations of the structure demonstrated in 1st Embodiment are applicable also to the light source lighting device of this embodiment.

  The first time information and the second time information are appropriately set according to the characteristics and number of the light emitting elements 4 and the operating environment. The first time information and the second time information may set the same time, or may set different times.

  In addition, in the light source lighting device of the present embodiment, when applying the configuration in which the voltage control by the output voltage control circuit 6 is continued even if the illuminance is changed after the voltage control by the output voltage control circuit 6 is started, The second time information is not necessary.

(Third embodiment)
FIG. 4 is a block diagram showing a configuration of a light source lighting device according to the third embodiment of the present invention.

  The light source lighting device of this embodiment is different from that of the first embodiment in that a timer circuit 81 is provided instead of the timer circuit 8.

  The lighting signal S1 and the drive current variable signal S2 are supplied to the converter circuit 3a and the timer circuit 81.

  The timer circuit 81 has first and second timers. When the lighting signal S1 is turned on, the first timer measures the duration time of the ON state, and outputs a first instruction signal indicating that when the measurement time reaches the first time. When the set value of the drive current variable signal S2 is changed, the second timer measures the duration of the state in which the changed set value from the change point is maintained, and the measurement time is set to the second time. When it reaches, a second instruction signal indicating that is output.

  When the output voltage control circuit 6 receives the first instruction signal from the first timer, the output voltage control circuit 6 determines that the lighting operation state of the light emitting element 4 is stable after lighting. Thereby, the output voltage control circuit 6 can recognize the timing of the time T3 shown in FIG.

  Further, when receiving the second instruction signal from the second timer, the output voltage control circuit 6 determines that the lighting operation state of the light emitting element 4 is stable after changing the illuminance. Thereby, the output voltage control circuit 6 can recognize the timing of the time T5 shown in FIG.

  Since operations other than the timing determination using the timer circuit 81 are the same as those in the first embodiment, description thereof is omitted here.

  The light source lighting device of the present embodiment also has the same effects as those of the first embodiment.

  Moreover, all the variations of the structure demonstrated in 1st Embodiment are applicable also to the light source lighting device of this embodiment.

  Note that the first time used for the determination by the first timer and the second time used for the determination by the second timer are appropriately set according to the characteristics and number of the light emitting elements 4 and the operating environment. The first time and the second time may be set to the same time, or may be set to different times.

  In addition, in the light source lighting device of the present embodiment, when applying the configuration in which the voltage control by the output voltage control circuit 6 is continued even if the illuminance is changed after the voltage control by the output voltage control circuit 6 is started, The second timer is not necessary.

  In the light source lighting device of each embodiment described above, the DC / DC converter unit 2 may be configured with an insulating step-down converter. Thereby, it is possible to treat the light emitting element 4 as a secondary side.

(Electronics)
The light source lighting device of each embodiment described above can be applied to an electronic device including a light source such as an LD or an LED, for example, a display device such as a projector or a liquid crystal display device.

  FIG. 5 shows an example of the display device.

  Referring to FIG. 5, the display device includes a light source lighting device 10, a light source 11, a display panel 12, a control unit 13, and an input unit 14.

  The light source 11 includes a light emitting element such as an LD or an LED. In this example, the light source 11 is composed of a plurality of light emitting elements connected in series. The light source lighting device 10 lights the light source 11 and is configured by any of the light source lighting devices of the first to third embodiments described above.

  The display panel 12 forms or displays an image by spatially or temporally modulating light from the light source 11. For example, the display panel 12 is configured by a liquid crystal panel.

  The input unit 14 has a plurality of operation keys and operation buttons. The operator performs an input operation necessary to operate the display device using the input unit 14. The input unit 14 supplies an instruction signal corresponding to the input operation by the operator to the control unit 13.

  The control unit 13 controls the operation of the entire display device. For example, the control unit 13 controls the operation of the light source lighting device 10 and the display panel 12 in accordance with an instruction signal from the input unit 14.

  In the control of the light source lighting device 10, the control unit 13 can perform the same operation as the CPU unit 5 described in the first to third embodiments.

  Specifically, when the light source lighting device 10 is the light source lighting device of the first embodiment, the control unit 13 receives the lighting signal S1 and the drive current variable signal S2 as in the CPU unit 5 shown in FIG. The signal is supplied to the converter circuit 3 a of the light source driving unit 3, and the ON / OFF signal S 3 is supplied to the output voltage control circuit 6 of the DC / DC converter unit 2. The control unit 13 includes information on the time from the lighting start time until the lighting operation state of the light emitting element 4 is stabilized (for example, the time corresponding to the period of time T1 to T3 illustrated in FIG. 2) and the light emitting element from the time of changing the illuminance Information of time until the lighting operation state 4 is stabilized (for example, time corresponding to the period of time T4 to T5 shown in FIG. 2) is held in advance.

  When the light source lighting device 10 is the light source lighting device of the second embodiment, the control unit 13 converts the lighting signal S1 and the drive current variable signal S2 into the converter circuit 3a and the DC / DC converter unit of the light source driving unit 3. 2 is supplied to the output voltage control circuit 6. In this case, the control unit 13 needs to hold time information from the lighting start time until the lighting operation state of the light emitting element 4 is stabilized and time information from the illuminance change time until the lighting operation state of the light emitting element 4 is stabilized. There is no.

  When the light source lighting device 10 is the light source lighting device of the third embodiment, the control unit 13 converts the lighting signal S1 and the drive current variable signal S2 into the converter circuit 3a and the DC / DC converter unit of the light source driving unit 3. 2 timer circuit 81. Also in this case, the control unit 13 needs to hold time information from the lighting start time until the lighting operation state of the light emitting element 4 is stabilized and time information from the time of changing the illuminance until the lighting operation state of the light emitting element 4 is stabilized. There is no.

  In the display device described above, another component that uses light from the light source 11 may be used instead of the display panel 12. Another component is, for example, a lighting device.

  The light source lighting device and the electronic device including the light source lighting device according to each embodiment described above are examples of the present invention, and the configuration and operation thereof can be appropriately changed within a range that can be understood by those skilled in the art.

  For example, the control unit 13 and the input unit 14 illustrated in FIG. 5 may be added to each of the light source lighting devices of the first to third embodiments.

  In addition, a sensor for detecting the temperature of the light emitting element 4 is provided, and the output voltage control circuit 6 indicates that the lighting operation state of the light emitting element 4 is in a state where the detected temperature of the light emitting element 4 detected by the sensor exceeds the threshold value. You may determine that it was stable. In this case, the threshold value may include a plurality of threshold values set for each set value of the drive current specified by the drive current variable signal S3.

  Moreover, although this invention can take a form like the following additional remarks 1-11, it is not limited to these forms.

(Appendix 1)
A light source lighting device for lighting a light emitting element,
A converter for converting an input voltage into a first voltage;
The light emitting element receives the first voltage output from the converter unit and a control signal indicating a driving current value of the light emitting element and inputs a driving current having a value indicated by the control signal to the light emitting element. A light source driving unit that changes an output voltage applied to
The converter unit fixes the first voltage to a predetermined voltage at the start of lighting of the light emitting element, and after lighting, the difference between the input voltage and the output voltage of the light source driving unit becomes a predetermined value. A light source lighting device for adjusting the first voltage.

(Appendix 2)
The light source driving unit is
The first voltage supplied from the converter unit is used as an input, a second voltage lower than the first voltage is supplied to the light emitting element, and the second voltage becomes an operation forward voltage of the light emitting element. A converter circuit that changes accordingly,
A voltage detector that detects the second voltage output from the converter circuit at a predetermined time interval;
The said converter part has an output voltage control circuit which makes the said 1st voltage what added the electric potential difference of the said predetermined value to the detection voltage of the said 2nd voltage detected by the said voltage detection part. Light source lighting device.

(Appendix 3)
The output voltage control circuit fixes the first voltage to the predetermined voltage until the first predetermined time elapses from the lighting start time of the light emitting element, and the first predetermined time elapses. After that, the light source lighting device according to appendix 2, wherein the first voltage is obtained by adding the potential difference of the predetermined value to the detection voltage of the second voltage detected by the voltage detection unit.

(Appendix 4)
The light source driving unit changes the amount of current flowing through the light emitting element according to the control signal,
The output voltage control circuit fixes the first voltage to the predetermined voltage until the second predetermined time elapses from the time when the current amount is changed, and the second predetermined time has elapsed. After that, the light source lighting device according to appendix 3, wherein the first voltage is obtained by adding the potential difference of the predetermined value to the detection voltage of the second voltage detected by the voltage detection unit.

(Appendix 5)
The converter unit further includes a timer for measuring time,
The output voltage control circuit activates the timer in response to a lighting start instruction, and determines whether or not the first predetermined time has elapsed based on a measurement time of the timer. Light source lighting device.

(Appendix 6)
The output voltage control circuit activates the timer in response to a change in drive current by the control signal, and determines whether or not the second predetermined time has elapsed based on a measurement time of the timer. 5. The light source lighting device according to 5.

(Appendix 7)
The converter unit further includes a first timer that measures an elapsed time according to a lighting start instruction,
The light source lighting device according to appendix 3 or 4, wherein the output voltage control circuit determines whether or not the first predetermined time has elapsed based on a measurement time of the first timer.

(Appendix 8)
The converter unit further includes a second timer that measures an elapsed time according to a change in driving current by the control signal,
The light source lighting device according to appendix 7, wherein the output voltage control circuit determines whether or not the second predetermined time has elapsed based on a measurement time of the second timer.

(Appendix 9)
A sensor for detecting the temperature of the light emitting element;
The light source lighting according to appendix 3 or 4, wherein the output voltage control circuit determines that a time when the detected temperature of the light emitting element detected by the sensor exceeds a threshold is a time when the first predetermined time has elapsed. apparatus.

(Appendix 10)
A light source lighting method performed in an apparatus including a light source driving unit that receives a first voltage and changes an output voltage applied to the light emitting element so that a predetermined amount of driving current flows to the light emitting element,
The first voltage is fixed to a predetermined voltage at the start of lighting of the light emitting element, and the first voltage is set so that a difference between an input voltage and an output voltage of the light source driving unit becomes a predetermined value after lighting. Light source lighting method to adjust the voltage of the light source.

(Appendix 11)
A light emitting element;
A light source lighting device for lighting the light emitting element;
A control unit for controlling a lighting operation of the light source lighting device and supplying a control signal indicating a driving current value of the light emitting element to the light source lighting device;
The light source lighting device is:
A converter for converting an input voltage into a first voltage;
A light source driving unit that receives the first voltage output from the converter unit and changes an output voltage applied to the light emitting element so that a driving current having a value indicated by the control signal flows to the light emitting element; Have
The converter unit fixes the first voltage to a predetermined voltage at the start of lighting of the light emitting element, and after lighting, the difference between the input voltage and the output voltage of the light source driving unit becomes a predetermined value. An electronic device for adjusting the first voltage.

  In the above supplementary notes 1 to 11, the converter unit corresponds to the DC / DC converter unit 2, and the light source driving unit corresponds to the light source driving unit 3. The control signal corresponds to the drive current variable signal S2. The voltage detection unit corresponds to the output voltage detection circuit 7.

DESCRIPTION OF SYMBOLS 1 Power supply 2 DC / DC converter part 2a Converter circuit 3 Light source drive part 3a Converter circuit 4 Light emitting element 5 CPU part 6 Output voltage control circuit 7 Output voltage detection circuit

Claims (11)

A light source lighting device for lighting a light source,
A converter for converting an input voltage into a first voltage;
A light source driving unit that is supplied with the first voltage from the converter unit, receives a control signal indicating a driving current value of the light source, and controls a current flowing through the light source according to the control signal;
The light source driving unit detects a second voltage applied to the light source;
The converter unit fixes the first voltage to a predetermined voltage at the start of lighting of the light source, and then becomes a voltage obtained by adding a potential difference of a predetermined value to the detected second voltage . A light source lighting device for adjusting the first voltage . The light source lighting device according to claim 1, wherein the light source is a plurality of or one light emitting element . The converter unit, the elapsed until the amount of time from lighting start time point of the first light source, the Ru solid Teisu a first voltage to the predetermined voltage, the light source lighting device according to claim 1 or 2 . The converter unit in accordance with said control signal, between when the second elapsed until since the amount of current flowing to the light source is changed, fixed to the first voltage to the predetermined voltage, the second after the inter-time has elapsed, the first voltage is adjusted so that a potential difference of voltage obtained by adding a predetermined value to a second voltage the detection, the light source lighting device according to claim 3. The converter unit includes an output voltage control circuit for outputting the first voltage, and a timer for measuring time, possess,
The output voltage control circuit activates the timer in response to the lighting start instruction, determines whether or not elapsed between the time of the first on the basis of the measured time of the timer according to claim 3 or 4 Light source lighting device. The converter unit includes an output voltage control circuit that outputs the first voltage, and a timer that measures time.
The output voltage control circuit starts the timer in response to a lighting start instruction, determines whether or not the first time has elapsed based on a measurement time of the timer, and changes the drive current based on the control signal The light source lighting device according to claim 4 , wherein the timer is activated in accordance with and the second time is determined based on a measurement time of the timer. The converter unit includes an output voltage control circuit for outputting the first voltage, and a first timer for measuring the elapsed time according to the lighting start instruction, possess,
The output voltage control circuit determines whether elapsed between the time of the first on the basis of the time measured by the first timer, the light source lighting device according to claim 3 or 4. The converter unit includes: an output voltage control circuit that outputs the first voltage; a first timer that measures an elapsed time according to a lighting start instruction; and an elapsed time according to a change in drive current by the control signal. A second timer for measuring,
The output voltage control circuit determines whether the first time has elapsed based on the measurement time of the first timer, and determines the second time based on the measurement time of the second timer. The light source lighting device according to claim 4 , wherein it is determined whether or not the time has elapsed. The light source driving unit includes a voltage detection unit that detects a second voltage applied to the light source,
The light source lighting device according to any one of claims 1 to 8, wherein the second voltage is lower than the first voltage and changes in accordance with an operation forward voltage of the light source. A first voltage as an input, a light source lighting method prescribed amount of the driving current is performed in an apparatus having a light source driving unit for controlling to flow to the light source,
At the start of lighting of the light source , the first voltage is fixed to a predetermined voltage, and then a second voltage applied to the light source is detected, and a potential difference of a predetermined value is added to the detected second voltage. A light source lighting method of adjusting the first voltage so as to be an added voltage . A light source;
A light source lighting device for lighting the light source;
A control unit that controls a lighting operation of the light source lighting device and supplies a control signal indicating a driving current value of the light source to the light source lighting device;
The light source lighting device is:
A converter for converting an input voltage into a first voltage;
A light source driving unit that is supplied with the first voltage from the converter unit and controls a current flowing through the light source in accordance with the control signal;
The light source driving unit detects a second voltage applied to the light source;
The converter unit fixes the first voltage to a predetermined voltage at the start of lighting of the light source, and then becomes a voltage obtained by adding a potential difference of a predetermined value to the detected second voltage . An electronic device for adjusting the first voltage .

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