JP2017033645A - Light source device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable light output by a desired color mixture ratio while securing a dynamic range.SOLUTION: By means that power supply means 300 applies a voltage V to a plurality of light sources 11 in common, a comparison circuit 410 acquires light intensity of different color light R, G, B emitted by the light source 11, respectively, and the light intensity and a predetermined reference value SA determined for each of color light R, G, B are compared with each other, a drive signal SD for driving each of the plurality of light sources 11, and a first control part 100 adjusts the reference value SA determined for each of color light R,G,B based on change in the voltage V of the power supply means 300.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a light source device that emits illumination light when displaying an image.

  Patent Document 1 discloses a display device that uses a DMD (Digital Micro-mirror Device), which is a reflective display element, as a display device that displays an image by a field sequential color system. This type of display device generates a color image by reflecting illumination light emitted from a light source device by individual mirrors of a DMD based on a video signal from the outside.

  The display device disclosed in Patent Document 1 controls both a power supply voltage applied to each light source having a different emission color and a duty ratio for turning on / off the light source in order to ensure a dynamic range of luminance of the image. ing.

JP 2014-066920 A

  However, since the rate of change of the light output with respect to the change in voltage is different for each light source having a different emission color, there is a problem that the white balance (color mixture ratio) of the combined light when the colored light emitted from the light sources is combined is lost. It was.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a light source device capable of outputting light at a desired color mixture ratio while ensuring a dynamic range.

  In order to achieve the above object, a light source device according to the present invention is based on a plurality of light sources that emit colored light of different colors, a power supply unit that applies a common voltage to the plurality of light sources, and a required luminance. The power supply means that can adjust the voltage applied in common to the plurality of light sources, the light intensity of the different color light emitted by the light source, respectively, and the light intensity and a predetermined reference value defined for each color light By comparing, a pulse signal generation unit that generates a pulse signal that drives each of the plurality of light sources, a drive unit that turns on or off the light source based on the pulse signal generated by the pulse signal generation unit, and at least the Reference value adjusting means for adjusting the reference value determined for each color light based on a change in voltage.

  According to the present invention, it is possible to output light at a desired color mixture ratio while ensuring a dynamic range.

It is a schematic block diagram of the display apparatus in embodiment of this invention. It is a block diagram for demonstrating the electrical structure in the display apparatus of the said embodiment. It is a figure which shows the relationship of (a) light output P, (b) restriction | limiting signal, (c) reference signal, and (d) voltage signal with respect to the required brightness | luminance in the light source drive process of the said embodiment. (A)-(f) is a timing chart for demonstrating the various signals and drive current in a sub-frame process. It is a block diagram for demonstrating the electrical structure of the logic circuit in the said embodiment. It is a figure which shows the example of the flowchart of the light source drive process of the said embodiment. It is a figure which shows the example of the flowchart of the sub-frame process of the said embodiment.

  The embodiments described below are used to easily understand the present invention, and those skilled in the art should note that the present invention is not unduly limited by the embodiments described below.

  Hereinafter, an embodiment of the display device and the light source device of the present invention will be described. FIG. 1 is a diagram illustrating a configuration of a display device 1 according to the present embodiment. The display device 1 of the present embodiment includes a light source unit 10 that emits illumination light C and a convex lens, for example, and illumination optics that adjusts the illumination light C emitted from the light source unit 10 to a size corresponding to the display element 30. A display element 30 that receives the illumination light C that has passed through the system 20, the illumination optical system 20, and projects the image light L spatially modulated on the illumination light C toward the screen 50; The projection optical system 40 is composed of a convex lens or the like arranged on the optical path of the image light L to be directed, and efficiently projects the image light L from the display element 30 onto the screen 50, and receives the image light L that has passed through the projection optical system 40. And a screen 50 for displaying the image M. For example, a vehicle ECU 2 mounted on the vehicle is connected to the display device 1 so as to be able to send and receive electrical signals by wire or wirelessly. The display device 1 of the present embodiment can adjust the luminance of the image M based on a signal related to the required luminance SL input from the vehicle ECU 2.

1 includes a DMD (Digital Micro-mirror Device) having a plurality of movable micromirrors, and each mirror is controlled in either an on state or an off state. The image M is generated on the screen 50 by spatially modulating the illumination light C from the light. The display element 30 may be, for example, a reflective display element similar to DMD, such as LCoS (registered trademark: Liquid Crystal ON Silicon), or a transmissive display element such as a liquid crystal display element. .

Next, the light source unit 10 according to the present embodiment will be described in detail.

(Light Source Unit (Light Source Device) 10) As shown in FIG. 2, the light source unit (light source device) 10 includes a plurality of light sources 11 (11r) having different emission colors such as red light R, green light G, and blue light B, for example. , 11g, 11b), a first control unit 100, a second control unit 200, a power supply unit 300, a light source driving unit 400, and a light intensity detection unit 500. These are mounted on a circuit board (not shown) disposed in the light source unit 10, for example. In addition to the circuit board, some or all of the first control unit 100, the second control unit 200, the power feeding unit 300, and the light source driving unit 400 may be mounted.

The first control unit 100 includes, for example, a CPU (processing unit), a memory (storage unit), an input interface, and the like (not shown). The processing unit controls each unit by reading and executing a program necessary for the operation of the display device 1 stored in advance in the storage unit. A video signal (not shown) for displaying the image M is input from the outside of the display device 1 to the first control unit 100, and the requested luminance SL is received from the vehicle ECU 2 to the first control unit 100. Based on the input, the light output P of the light source 11 is adjusted, and a desired image M is displayed on the display element 30 via the second controller 200. The first control unit 100 outputs the video signal input from the vehicle ECU 2 to the second control unit 200 via an image processing IC (not shown). Note that the video signal input from the outside of the display device 1 does not directly pass through the first controller 100 but directly to the second controller 200 described later via an image processing IC (not shown) or the like. It may be entered.

The first control unit 100 controls each unit as follows in order to control the light source 11. (1) The first control unit 100 generates a reference signal (hereinafter also referred to as a reference value) SA based on the required luminance SL input from the vehicle ECU 2, and uses this reference signal SA as one of the comparison circuits 410. Output to the input terminal. Specifically, for example, the first control unit 100 refers to the table data in which the required luminance SL and the reference signal SA correspond from the storage unit, and the pulse signal corresponding to the acquired required luminance SL (hereinafter referred to as a PWM signal). This pulse signal is converted into a reference signal SA that is an analog signal by an analog converter including an integration circuit (not shown), and is output to a comparison circuit 410 described later. The frequency of the pulse signal for generating the reference signal SA output from the first control unit 100 is desirably 30 kHz or more. Note that the magnitude of the value of the reference signal SA associated with the required luminance SL differs for each color of light emitted from the light source 11. That is, the storage unit of the present embodiment stores in advance the table data in which the reference signal SA of each light source 11 is associated with each required luminance SL. As shown in FIG. 3B, the table data includes the first luminance La to the second luminance between the first luminance SLa and the second luminance SLb that is smaller than the first luminance SLa. The reference value SA is gradually decreased so that the ON driving of the light source 11 decreases toward Lb, and the reference signal SA is changed at a change point where a period signal SC described later changes stepwise from the first value Sca to the second value Scb. And the ON drive of the light source 11 decreases from the second luminance SLb toward the third luminance SLc between the second luminance SLb and the third luminance SLc, which is smaller than the second luminance SLb. Thus, the reference value SA is gradually decreased. As shown in FIG. 4, the first control unit 100 supplies a reference signal SA (SAr, SAg, SAb) having different magnitudes to the comparison circuit 410 for each of the subframes F1, F2, F3 that emit different colors. Is output. With such a configuration, even when the light intensity detection signal SFB of each color light is processed by the common comparison circuit 410, the light amount of each color light emitted from the light source 11 can be appropriately determined and adjusted. Further, the reference signal SA in the table data is individually determined for each light source 11 according to a change in the required luminance SL when the required luminance SL input from the vehicle ECU 2 is equal to or lower than a predetermined threshold required luminance SLp. It changes stepwise or continuously. Similarly, the voltage V of the power supply means 300 to be described later is also stepwise according to a change in the required luminance SL when the required luminance SL input from the vehicle ECU 2 is equal to or lower than a predetermined threshold required luminance SLp. Or it changes continuously. That is, when the required luminance SL input from the vehicle ECU 2 is equal to or lower than a predetermined threshold required luminance SLp, each light source 11 is individually selected according to a stepwise or continuous change in the voltage V of the power supply means 300. The reference signal SA is changed. In this way, the reference signal SA can be changed for each light source 11 and the light output P for each light source 11 can be adjusted according to the voltage V of the power supply means 300, so that the voltage applied to the light source 11 changes. However, the white balance (color mixing ratio) of the illumination light C can be adjusted appropriately.

(2) Further, the first control unit 100 outputs a period signal SC that regulates the period during which the light source 11 is driven to the input terminal of the logic circuit 420 via the second control unit 200. The period signal SC is, for example, a digital signal composed of on / off that defines a period for driving the light source 11 in the subframe. While the period signal SC is on, the driving of the light source 11 is permitted. Is turned off, and the light output P of the light source 11 can be adjusted by adjusting the period ratio (hereinafter also referred to as the period ratio) T during which the light source 11 is prohibited and is turned on in the subframe. The storage unit of the first control unit 100 of the present embodiment stores in advance the table data in which the period signal SC of each light source 11 is associated with each required luminance SL. In the table data, as shown in FIG. 3C, when the required luminance SL is between the first luminance SLa and the second luminance SLb, the period signal SC (period ratio T) is constant at the first value SCa. And the period signal SC (period ratio T) is kept constant at the second value Scb smaller than the first value SCa between the second luminance SLb and the third luminance SLc. The period ratio T) is changed stepwise. As shown in FIG. 4, the first control unit 100 sets the period signal SC having period ratios T (T1, T2, T3) having different lengths in the logic circuit 420 for each of the subframes F1, F2, F3. Is output. Thus, the color mixture ratio of the light source 11 can be adjusted with higher accuracy by adjusting the period ratio T for each sub-frame that emits different colors. The period signal SC may have a substantially uniform period ratio T for each subframe that emits different colors. Further, the period signal SC in the table data is kept constant regardless of the change in the required luminance SL when the required luminance SL input from the vehicle ECU 2 is equal to or lower than the predetermined threshold required luminance SLp.

(3) Moreover, the said memory | storage part of the 1st control part 100 of this embodiment has memorize | stored beforehand the said table data which matched the voltage V supplied to the light source 11 for every request | requirement brightness | luminance SL. 3D, the first control unit 100 refers to the table data, and the power supply unit 300 applies the table data to the light source 11 according to the required luminance SL. Adjust the voltage V. Specifically, for example, the first control unit 100 determines whether the required luminance SL input from the vehicle ECU 2 is less than the threshold required luminance SLp, and when the required luminance SL is equal to or higher than the threshold required luminance SLp, the required luminance SL When the voltage V applied to the light source 11 by the power supply means 300 is constant regardless of the required brightness SL and the required brightness SL is less than the threshold required brightness SLp, the voltage applied by the power supply means 300 to the light source 11 according to the required brightness SL is set. Change stepwise or continuously.

(4) In addition, the storage unit of the first control unit 100 of the present embodiment stores in advance the table data in which the gain adjustment signal SG of each light source 11 is associated with each required luminance SL. The first control unit 100 adjusts the amplification factor of the light intensity detection signal SFB in the amplifier circuit 440 by outputting the gain adjustment signal SG with reference to the table data for each sub-frame emitting different colors. Then, the magnitude (amplitude) of the light intensity detection signal SFB input to the comparison circuit 410 is made substantially uniform for each color or all colors. With such a configuration, even when the light intensity detection signal SFB of each color light is processed by the common comparison circuit 410, the light amount of each color light emitted from the light source 11 can be appropriately determined and adjusted.

The second control unit 200 is an LSI (Large Scale Integration) that realizes a desired function by hardware, and includes, for example, an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or the like. In addition, a storage unit (not shown) is connected to the second control unit 200, and data for outputting a period signal SC corresponding to a signal from the first control unit 100, Data for controlling the enable signal EN (R-EN, G-EN, B-EN) for controlling the light emission timing of the light source 11 according to the illumination control data from the first control unit 100, or the first control unit Data for controlling the display element 30 according to display control data from 100 is stored.

The power supply unit 300 includes a power supply IC (Integrated Circuit), a switching circuit using a transistor, and the like. The power supply unit 300 reduces the voltage from the battery (not shown) of the vehicle and applies a voltage V having an appropriate value to the light source 11 under the control of the first control unit 100. The power feeding means 300 is connected to the anode side of the light sources 11r, 11g, and 11b as shown in FIG. Thus, by providing a common supply voltage line on the anode side of each color LED, the number of components such as the power supply means 300 and the number of wirings can be reduced. The power supply unit 300 may be integrated into an LSI of the light source driving unit 400 described later.

The light source driving unit 400 is an LSI that realizes a desired function by hardware, and is configured by, for example, an ASIC or FPGA independent of the second control unit 200. The light source driving unit 400 includes a comparison circuit 410, a logic circuit 420, a switch unit 430, and an amplification circuit 440. The illumination light C (blue light B, green light G, or red light R) emitted from the light source 11 is provided. A light intensity detection signal SFB based on the light intensity is amplified and inputted from the light intensity detection unit 500, and a drive signal SD for driving the light source 11 is generated from the light intensity detection signal SFB, and based on this drive signal SD The light source 11 is turned on / off by the on / off operation of the switch means 430.

The comparison circuit 410 includes a comparator, and compares the light intensity detection signal SFB output from the light intensity detection unit 500 (amplification circuit 440) with the reference signal SA output from the first control unit 100. The comparison signal SB is output to the logic circuit 420 as a comparison result.

For example, as illustrated in FIG. 5, the logic circuit 420 includes a first AND circuit 421, a red AND circuit 422, a green AND circuit 423, and a blue AND circuit 424. The logic circuit 420 compares the period signal SC, the enable signal EN (red enable signal R-EN, green enable signal G-EN, blue enable signal B-EN) from the second controller 200 and the comparison circuit 410. The signal SB is input, and a red drive signal SDR that drives the red light source 11r, a green drive signal SDG that drives the green light source 11g, or a blue drive signal SDB that drives the blue light source 11b is red by using these AND circuits. The signals are output to the switch means 431, the green switch means 432, and the blue switch means 433, respectively.

The first AND circuit 421 outputs a drive signal SD that is an AND signal of the period signal SC from the second control unit 200 and the comparison signal SB from the comparison circuit 410 to each AND circuit 422, 423, 424. .

The red AND circuit 422 outputs a red drive signal SDR that is an AND signal of the red enable signal R-EN from the second control unit 200 and the drive signal SD from the first AND circuit 421 to the red switch unit 431. Similarly, the green AND circuit 423 outputs a green drive signal SDG, which is an AND signal of the green enable signal G-EN from the second control unit 200 and the drive signal SD from the first AND circuit 421, to the green switch unit 432. Similarly, the blue AND circuit 424 also outputs a blue drive signal SDB that is an AND signal of the blue enable signal B-EN from the second control unit 200 and the drive signal SD from the first AND circuit 421 to the green switch. Output to means 432.

The switch means 430 is formed of a switching circuit using, for example, an n-type channel or p-type channel FET (Field Effect Transistor). The switch means 430 performs an on / off operation according to the output from the logic circuit 420. 2, for example, as shown in FIG. 2, the red switch means 431 connected to the cathode side of the red light source 11r, the green switch means 432 connected to the cathode side of the green light source 11g, and the cathode side of the blue light source 11b. It has blue switch means 433 connected. The red switch means 431 corresponding to the red light source 11r is turned on when the output of the red AND circuit 422 is turned on (High), whereby the drive current IR (see FIG. 4F) is supplied to the red light source 11r. The supplied red light source 11r emits red light R. When the output of the red AND circuit 422 indicates OFF (Low), the red light source 11r is turned off. Similarly, the green light source 11g emits green light G when the green AND circuit 423 corresponding to the green light source 11g is on, and the blue light source 11b when the blue AND circuit 424 corresponding to the blue light source 11b is on. Emits blue light B.

As shown in FIG. 4 (f), the light source driving means 400 configured as described above causes each of the light sources 11r, 11g, and 11b to have a driving current according to the light emission timing determined by each enable signal R, G, B-EN. Will be supplied. Thereby, the light sources 11r, 11g, and 11b of different colors are sequentially turned on every predetermined period (period in which the enable signal indicates ON) (field sequential color system). Note that IR shown in FIG. 4F indicates a drive current flowing through the red light source 11r, IG indicates a drive current flowing through the green light source 11g, and IB indicates a drive current flowing through the blue light source 11b.

The light intensity detection unit 500 includes, for example, a light receiving element having a photodiode, receives the illumination light C emitted from the light source 11, and detects the light intensities of the lights R, G, and B in a time division manner. The light intensity detection unit 500 outputs a light intensity detection signal SFB indicating the detected light emission intensity to the light source driving means 400 (amplifying circuit 440). As described above, in the light source unit 10 of the present embodiment, the light intensity detection signal SFB indicating the light emission intensity of the light source 11 input by the light intensity detection unit 500 is input, and the light source driving unit 400 receives the light intensity detection signal. A drive signal SD (a red drive signal SDR, a green drive signal SDG, and a blue drive signal SDB) is generated from the SFB, and feedback control for driving the light source 11 of each color again is performed based on the drive signal SD, so that the light source 11 Monitoring control is performed so as to obtain a desired light emission intensity.

From here, the light source drive process which the light source part (light source device) 10 performs is demonstrated mainly with reference to the flowchart shown in FIG. 6, FIG. This process is started when the display device 1 is activated, for example, and is repeated until the display device 1 is stopped.

(Light source drive process) First, the 1st control part 100 of the light source part 10 inputs the request | requirement brightness | luminance SL which shows external brightness from vehicle ECU2 in step S10.

Next, in step S20, the first control unit 100 selects the table data corresponding to the input requested luminance SL from the storage unit, and outputs various signals based on the read table data in step S30. To do. Specifically, for example, the first control unit 100 refers to the storage unit and associates the voltage signal SV associated with the requested luminance SL input at step S10 and the requested luminance SL input at step S10. The reference signal SA, the period signal SC, and the gain signal SG provided to each of the light sources 11 having different emission colors are read, the reference signal SA is output to the comparison circuit 410, and the period signal SC is output to the second control unit. 200 (logic circuit 420), gain signal SG is output to amplifier circuit 440, and voltage signal SV is output to power supply means 300. And it transfers to the sub-frame process (step S40) which the light source drive means 400 performs.

The subframe processing in step S40 is repeated for each subframe obtained by time-dividing one frame, and the subframe processing ends after one frame is completed. Even after the subframe processing is completed, the process returns to step S10 and the light source drive processing is repeated until the display device 1 is stopped. A description will be given below with reference to FIG. 7 showing a flowchart of the subframe processing and FIG. 4 showing a timing chart for explaining various signals and driving currents in the subframe processing.

(First Subframe Processing) In the first subframe processing, the comparison circuit 410 of the light source unit 10 relates to the light intensity of the illumination light C emitted from the light source 11 from the light intensity detection unit 500 via the amplifier circuit 440. A light intensity detection signal SFB, which is a value, is input (step S41), the light intensity detection signal SFB is compared with the reference signal SA input from the first control unit 100, and the comparison is a pulse signal that is turned on / off. A signal SB is generated (step S42). Specifically, as shown in FIGS. 4B and 4C, when the value of the light intensity detection signal SFB exceeds the set value indicated by the reference signal SA, the comparison circuit 410 turns off the comparison signal SB ( (Low) signal. When the comparison signal SB is turned off in this way, as will be described in detail later, since the drive current flowing through the light source 11 decreases, the light intensity of the illumination light C emitted from the light source 11 decreases, and the light intensity detection unit 500 The value of the detected light intensity detection signal SFB falls and falls below the value of the reference signal SA. The comparison circuit 410 outputs the comparison signal SB as an ON signal this time at the timing when the value of the light intensity detection signal SFB falls below the value of the reference signal SA. By repeating this operation, the comparison circuit 410 generates a comparison signal SB that is a pulse signal that repeatedly turns on and off.

In step S43, the first AND circuit 421 of the logic circuit 420 receives the period signal from the second control unit 200 (first control unit 100) as shown in FIGS. 4C, 4D, and 4E. The drive signal SD is generated by ANDing the SC (the enable signal SC1 and the inhibit signal SC2) and the comparison signal SB from the comparison circuit 410, and output to the AND circuits 422, 423, and 424. In the second subframe processing, the first AND circuit 421 outputs a logical product of the comparison signal SB and a signal indicating ON (High) and a signal indicating OFF (Low) as the drive signal SD. When the period signal SC is on (High), the drive signal SD (lighting signal SD1), which is a pulse signal equivalent to the comparison signal SB, is output. When the period signal SC is off (Low), the comparison signal SB is output. A drive signal SD (non-lighting signal SD2) that is not based on the pulse signal is output to the AND circuits 422, 423, and 424 in FIG. The AND circuits 422, 423, and 424 perform an AND operation on the drive signal SD from the first AND circuit 421 and the enable signal EN from the second control unit 200, and each drive signal SD (red drive signal SDr). Or the green drive signal SDg or the blue drive signal SDb).

Note that the period signal SC is an ON signal for a period ratio T (T1, T2, T3 in FIG. 4D) determined for each subframe, and is an OFF signal in other periods. Of the comparison signal SB that is a pulse signal from the comparison circuit 410, the second control unit 200 reads the leading edge (pulse) of the comparison signal SB input at the beginning of each subframe (F1, F2, F3...). When the signal rises), the lighting signal SD1 is output to the logic circuit 420 for a predetermined period ratio T. The logic circuit 420 outputs a drive signal SD (lighting signal SD1), which is a pulse signal based on the comparison signal SB only during the period ratio T, to each switch unit 430, and in other subframe periods, A drive signal SD (non-lighting signal SD2) that is not based on the pulse signal of the comparison signal SB is output to each switch means 430.

Then, the switch unit 430 performs an on / off operation according to the drive signal SD, and drives the light sources 11r, 11g, and 11b (step S44). At this time, the amplitudes of the drive current Ir flowing through the red light source 11r, the drive current Ig flowing through the green light source 11g, and the drive current Ib flowing through the blue light source 11b shown in FIG. Is done. That is, it is adjusted by the voltage signal SV output from the first control unit 100 to the power supply means 300 in step S30. The light source unit 10 repeats the above subframe processing S40 until one frame is completed.

As described above, the light source unit (light source device) 10 in the present embodiment includes a plurality of light sources 11 that emit color lights of different colors, a power supply unit 300 that applies a common voltage V to the plurality of light sources 11, and Based on the required luminance SL, the power supply means 300 that can adjust the voltage V applied in common to the plurality of light sources 11, and the light intensities of the different colored lights R, G, and B emitted from the light sources 11 are acquired, By comparing the light intensity with a predetermined reference value SA determined for each of the color lights R, G, and B, pulse signal generation means (comparison) that generates a pulse signal (drive signal) SD for driving each of the plurality of light sources 11 Circuit) 410, drive means (switch means) 430 for turning on or off the light source 11 based on the drive signal SD generated by the pulse signal generation means, and at least for each of the color lights R, G, B based on the change in the voltage V Reference value adjusting means for adjusting the reference value SA includes a (first control unit) 100, a. With such a configuration, the reference signal SA can be changed for each light source 11 and the light output P for each light source 11 can be adjusted according to the voltage V of the power supply means 300, so that the voltage applied to the light source 11 changes. Even so, the white balance (color mixture ratio) of the illumination light C can be adjusted appropriately.

Further, it further comprises period ratio changing means (first control unit) 100 capable of changing the period ratio T during which the drive signal SD is transmitted from the comparison circuit 410 to the switch means 430 within a predetermined time (subframe). The period ratio changing means (control unit) 100 sends the first period signal SC (period ratio T) between the first luminance SLa and the second luminance SLb smaller than the first luminance SLa. Between the second luminance SLb and the third luminance SLc smaller than the second luminance SLb, the period signal SC (period ratio T) is kept at the value SCa, and the second value SCb smaller than the first value SCa. The constant signal is changed stepwise by changing the period signal SC (period ratio T), and the reference value adjusting means (first control unit) 100 has the required luminance SL as the first luminance SLa and the first luminance SLa. Between two brightness SLb The reference value SA is gradually changed (gradually decreased) so that the ON drive of the light source 11 decreases from the first luminance SLa toward the second luminance SLb, and the period signal SC (period ratio T) is changed from the first value SCa to the first value SCa. The reference value SA is increased at a change point where the value SCb changes to 2, and when the required luminance SL is between the second luminance SLb and the third luminance SLc, the light source increases from the second luminance SLb toward the third luminance SLc. 11 is gradually changed (gradually reduced) so that the ON driving of 11 decreases, and the required luminance SL does not overlap between the first luminance SLa and the third luminance SLc. The power supply means 300 decreases the voltage V stepwise or continuously in the direction from the fourth brightness SLd to the fifth brightness SLe, and the reference value adjustment means (first value Control unit 100, intermittently or continuously smaller in accordance with the reference value SA to the change of the voltage V of the power supply means 300.

In addition, this invention is not limited by the above embodiment and drawing. Changes (including deletion of constituent elements) can be added to the embodiments and the drawings as appropriate without departing from the scope of the present invention.

In the embodiment described above, the light output P of each of the plurality of light sources 11 is adjusted based on the required luminance SL input from the vehicle ECU 2, but is not limited thereto. For example, the display device 1 may include an illuminance sensor that obtains external light intensity, and may adjust (light control) the light output P of the light source 11 based on an illuminance signal from the illuminance sensor provided in the display device 1. . In addition, an operation unit (not shown) provided in the display device 1 or the vehicle may be provided, and the display device 1 may be dimmed based on an operation signal from the operation unit. Moreover, the display apparatus 1 may adjust light according to operation of the switch which turns on / off the light of a vehicle.

1 Display 2 Vehicle ECU
10 Light source section (light source device)
DESCRIPTION OF SYMBOLS 11 Light source 20 Illumination optical system 30 Display element 40 Projection optical system 50 Screen 100 1st control part 110 Power supply means 200 2nd control part 300 Power supply means 400 Light source drive means 410 Comparison circuit 420 Logic circuit 430 Switch means 440 Amplifier circuit 500 Light intensity detector


C Illumination light L Image light La First luminance Lb Second luminance M Image P Light output SA Reference signal (reference value)
SB comparison signal SC period signal SCa first value SD drive signal SG gain signal SL required luminance (luminance)
SV voltage signal T period ratio V voltage

Claims (2)

A plurality of light sources that emit color lights of different colors, a power supply unit that applies a common voltage to the plurality of light sources, and a voltage that is commonly applied to the plurality of light sources can be adjusted based on required luminance A pulse signal that drives each of the plurality of light sources by acquiring light intensity of different color lights emitted from the light source and comparing the light intensity with a predetermined reference value determined for each of the color lights. A pulse signal generating means for generating the light source, a driving means for turning on or off the light source based on the pulse signal generated by the pulse signal generating means, and the reference set for each color light based on at least a change in the voltage And a reference value adjusting means for adjusting the value. It further comprises period ratio changing means capable of changing a ratio of the period during which the pulse signal is transmitted from the pulse signal generating means to the driving means within a predetermined time, and the period ratio changing means has the required luminance. Between the first luminance and the second luminance smaller than the first luminance, the period ratio is kept constant at the first value, and between the second luminance and the third luminance smaller than the second luminance. Then, by keeping the period ratio constant at a second value smaller than the first value, the period ratio is changed stepwise, and the reference value adjusting means has the required luminance Between the first luminance and the second luminance, the reference value is gradually changed so that the on-drive of the light source decreases from the first luminance toward the second luminance, and the period ratio is the first luminance. Change from a value of 1 to the second value The reference value is increased at the conversion point, and when the required luminance is between the second luminance and the third luminance, the on-drive of the light source decreases from the second luminance toward the third luminance. The reference value is gradually changed as follows, between the fourth luminance that does not overlap between the first luminance and the third luminance and the fifth luminance that is smaller than the fourth luminance, The power supply means decreases the voltage stepwise or continuously as the fourth brightness moves from the fourth brightness to the fifth brightness, and the reference value adjusting means changes the reference value to the change in the voltage of the power supply means. The light source device according to claim 1, wherein the light source device is intermittently or continuously reduced in response.

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