JP6908507B2 - Backlight device and display device - Google Patents

Description

The present invention relates to a backlight device and a display device that divide an area and individually adjust the brightness.

A non-light emitting display device such as a liquid crystal display is provided with a backlight device as a light source. From the viewpoint of long life, low power consumption, and the like, attention is being paid to a backlight device in which LEDs (Light Emitting Diodes) are arranged on the back surface of the display device to form a light source area with each LED.

The configuration of such a backlight device will be described with reference to FIGS. 18 to 20.

The image display device 200 shown in FIG. 18 expands the dynamic range of the displayed image by controlling the brightness of the light source of the backlight device installed on the back surface according to the image signal. The image display device 200 includes a display panel 110 such as a liquid crystal panel, a display driver 130 for writing display data to the display panel 110, a backlight panel 140, and an LED driver 160 for driving the LED 170. Further, the video display device 200 includes a display driver 130 and a timing controller 180 that controls the LED driver 160 as a control system.

The timing controller 180 includes a first timing controller 120 that supplies display data, control signals, and the like of the video display device 200 to the display driver 130, and a second timing controller 150 that controls the brightness of the LED 170.

Further, LEDs 170 are arranged on the backlight panel 140 at substantially even intervals. Four LEDs 170 form one area, and each of them is connected to the LED driver 160.

As shown in FIG. 19, the timing controller 180 supplies the control signal CTL and the luminance data DATALED driver 160.

As shown in FIG. 20, the LED driver 160 includes at least the number of LED drive units 161 corresponding to the number of LEDs 170 to be driven. The timing controller 180 selects one from a plurality of LED drive units 161 in the LED driver 160 by the control signal CTL, and outputs the brightness data DATA indicating the brightness to the selected LED drive unit 161. The LED driver 160 operates the selected LED drive unit 161 to light the LED 170 corresponding to the LED drive unit 161.

The DA converter 161a in the LED drive unit 161 outputs the corresponding voltage Vref by converting the luminance data DATA into analog. A current corresponding to the voltage Vref flows through the LED 170 through the LED 50 (LED element) by the feedback circuit composed of the operational amplifier 161a, the transistor 161c, and the resistor 161d. As a result, the brightness of the LED 170 is adjusted to a desired brightness represented by the brightness data DATA.

In the above configuration, since wiring for connecting one LED 170 to one LED driving unit 161 is required, there is a problem that the more LEDs 170 are, the more wiring is required.

In order to solve such a problem, it is possible to reduce wiring by arranging a plurality of light emitting elements in a matrix and writing display data for each selection line as in the light emitting device described in Patent Document 1. Conceivable.

Further, the backlight described in Patent Document 2 has a configuration in which a plurality of LED drivers cascaded to each other are sequentially enabled by transferring an enable signal, so that data is received from a serious bus and wiring is reduced. There is.

Japanese Unexamined Patent Publication No. 2012-58428 (published on March 22, 2012) Japanese Unexamined Patent Publication No. 2009-86621 (published on April 23, 2009)

However, in the techniques described in Patent Documents 1 and 2, the substrate on which the light emitting element is formed and the substrate on which the driver is mounted are separately provided, which increases the number of parts.

In order to reduce the number of parts, for example, it is conceivable to mount the driver on the substrate on which the light emitting element is mounted.

However, on the substrate, the light emitting element closer to the driver, which is the heat generating source, is affected by heat, so that there is a difference in the influence of heat received between such a light emitting element and the light emitting element far from the driver. In particular, since a light emitting element such as an LED has a characteristic that the brightness and chromaticity change depending on the temperature, the brightness and chromaticity due to the temperature characteristic are measured between the light emitting element close to the driver and the light emitting element far from the driver. There will be variations.

One aspect of the present invention is to reduce the number of parts of the backlight and to make the influence of heat on each light emitting element constituting the backlight uniform.

In order to solve the above problems, the backlight device according to one aspect of the present invention is driven by a substrate, a plurality of LED drivers arranged in a matrix on the substrate, and each LED driver. It is provided with a plurality of LED elements arranged around the substrate and a plurality of heat generating sources arranged around the substrate.

According to one aspect of the present invention, the number of parts of the backlight can be reduced, and the influence of heat on each light emitting element constituting the backlight can be made uniform.

It is a block diagram which shows the structure of the image display device which includes the structure of each embodiment of this invention. It is a block diagram which shows the connection structure of the backlight panel and the 2nd timing controller provided in the said video display device. It is a circuit diagram which shows the structure of the LED driver of the reference example provided in the said image display device. It is a timing chart which shows the operation of the LED driver shown in FIG. It is a circuit diagram which shows the structure of the LED driver of another reference example provided in the said image display device. It is a timing chart which shows the operation of the LED driver shown in FIG. It is a circuit diagram which shows the structure of the LED driver which concerns on Embodiment 1 of this invention. It is a timing chart which shows the operation of the LED driver shown in FIG. 7. It is a circuit diagram which shows the structure of the LED driver which concerns on Embodiment 2 of this invention. It is a timing chart which shows the operation of the LED driver shown in FIG. (A) and (b) are timing charts showing other operations of the LED driver shown in FIG. It is a circuit diagram which shows the 1st structure of the LED driver which concerns on Embodiment 3 of this invention. It is a circuit diagram which shows the 2nd structure of the LED driver which concerns on Embodiment 3 of this invention. It is a circuit diagram which shows the 3rd structure of the LED driver which concerns on Embodiment 3. It is a circuit diagram which shows the 4th structure of the LED driver which concerns on Embodiment 3. It is a figure which shows the structure of the backlight panel which concerns on Embodiment 4 of this invention. It is a figure which shows the structure of the backlight panel which concerns on the comparative example of Embodiment 4. It is a block diagram which shows the structure of the conventional video display device. It is a block diagram which shows the connection relationship between the LED driver and LED in the image display device of FIG. It is a circuit diagram which shows the structure of the LED driver of FIG.

[Video display device]
An image display device including the configurations of the first to fourth embodiments described later will be described. FIG. 1 is a block diagram showing the configuration of the video display device 1. FIG. 2 is a block diagram showing a configuration of a backlight panel 40 provided in the video display device 1.

(Overall configuration of video display device 1)
As shown in FIG. 1, the image display device 1 dynamically controls the brightness of the LEDs 50 as a plurality of light sources of the backlight panel 40 installed on the back surface of the display panel 10 according to the image signal. It is a display device that expands the range.

The image display device 1 is roughly classified into a display panel 10 composed of a liquid crystal panel or the like, a timing controller 20, a display driver 30, and a backlight panel 40.

The timing controller 20 includes a first timing controller 21 and a second timing controller 22. The first timing controller 21 extracts display data and control signals from the video signal and gives them to the display driver 30. The second timing controller 22 generates luminance data and a control signal from the video signal and feeds them to the LED driver 60. In the image display device 1, the backlight device is composed of the second timing controller 22 and the backlight panel 40.

The display driver 30 is a circuit that writes display data to a plurality of pixels (not shown) configured on the display panel 10.

The backlight panel 40 irradiates the display panel 10 with light from behind the display panel 10. The backlight panel 40 has a substrate 40a, a plurality of LEDs 50, and a plurality of LED drivers 60. A plurality of LEDs 50 are arranged in a matrix on the substrate 40a at substantially equal intervals. The four LEDs 50 constitute one area. Further, the backlight panel 40 is equipped with a plurality of LED drivers 60 that are smaller than the LED drivers of the prior art.

The LED driver 60 controls the lighting brightness of the LED 50 based on the control information. The LED drivers 60 are arranged at the centers of the four LEDs 50 so that they are arranged at substantially even intervals in the backlight panel 40. Further, the distance between the LED driver 60 and the LED 50 arranged around the LED driver 60 is substantially equal. Further, the LED drivers 60 arranged in each row direction are serially connected to the second timing controller 22.

The number of LEDs 50 arranged around the LED driver 60 with one LED driver 60 at the center is not limited to four, and may be two, three, or five or more.

One LED driver 60 drives four LEDs 50 arranged around the LED driver 60 based on the brightness data and the control signal from the second timing controller 22. The number of LEDs 50 driven by the LED driver 60 is not limited to four.

Further, the image display device 1 includes LED drivers 60A to 60E (see FIGS. 3, 5, 7, 9, and 12) described later as LED drivers 60.

(Connection configuration of LED driver 60 and second timing controller 22)
As shown in FIG. 2, in the backlight panel 40, m × n LED drivers 60 are arranged in a matrix of m columns and n rows.

The luminance data DATA (control information, digital signal) and control signal CTL from the second timing controller 22 are input to the first m LED drivers 60 (1-1) to 60 (m-1) in each column. .. Further, the luminance data DATA and the control signal CTL are n-1 LDE drivers 60 (1-2) to 60 (1-n), 60 (2-2) to be provided in the second and subsequent stages of each row. The data is sequentially transferred to 60 (2-n), ..., 60 (m-2) to 60 (mn). The method of transferring the luminance data DATA and the control signal CTL will be described in detail later.

[Reference column 1]
(Configuration of LED driver 60A)
The LED driver of Reference Example 1 which is a premise of the LED drivers 60C to 60E of the first to third embodiments to be described later will be described.

FIG. 3 is a circuit diagram showing the configuration of the LED driver 60A according to this reference example.

Although one LED drive unit 61 is drawn in FIG. 3, the LED driver 60A has four LED drive units 61 for driving the four LEDs 50. The fact that the four LED drive units are provided in this way is the same for the LED drivers 60B to 60E shown in FIGS. 5, 7, 9 and 12, which will be described later.

Alternatively, the LED driver 60A shown in FIG. 3 has the same drive current by sharing the DA converter 61a for the four LEDs 50, and controls the individual brightness of the four LEDs 50 by the PWM control used in the first to third embodiments. You may. Such a configuration can also be adopted in the LED driver 60B shown in FIG. 5, which will be described later.

As shown in FIG. 3, the LED driver 60A according to this reference example includes an LED drive unit 61, an SP counter 62, a data latch circuit 63, a start pulse output unit 64, and a clock output unit 65. There is.

The LED drive unit 61 includes a DA converter 61a, an operational amplifier 61b, a transistor 61c, and a resistor 61d. The LED drive unit 61 is configured in the same manner as the conventional LED driver 160 (see FIG. 20).

The DA converter 61a converts the input data into an analog reference voltage Vref. The operational amplifier 61b outputs a voltage corresponding to the difference between the reference voltage Vref input to one input terminal and the voltage input to the other input terminal.

The output voltage of the operational amplifier 61b is input to the gate of the transistor 61c. The cathode of the LED 50 is connected to the drain of the transistor 61c. The source of the transistor 61c is connected to the ground line via the resistor 61d and is connected to the other input terminal of the operational amplifier 61b. The anode of the LED 50 is connected to the power supply. A drive current corresponding to the reference voltage Vref flows through the LED 50 by the feedback circuit including the operational amplifier 61b and the transistor 61c. As a result, the LED 50 is adjusted to a desired brightness represented by the brightness data DATA.

The start pulse SP input to the SP counter 62 is one of the control signal CTLs, and is a pulse output immediately before a data string in which one line of luminance data DATA is connected. The second timing controller 22 sets the luminance data DATA, the start pulse SP, and the clock CLK to each other in advance so that the data latch in the LED driver 60A of each stage is properly performed according to the output timing of the start pulse SP. It is output at the timing.

The SP counter 62 is a counter that counts the start pulse SP. When the SP counter 62 counts the start pulse SP up to a predetermined set value, the SP counter 62 outputs an enable signal ENB from the enable terminal EN. The enable signal ENB is a signal required for the data latch circuit 63 to start data acquisition. The SP counter 62 has a k-bit setting terminal for determining the above setting value. For example, when the count value is 3 bits (k = 3) shown in FIG. 3, the count value can be set from 1 to 8.

Further, the SP counter 62 delays the input start pulse SP to the end timing of the serial luminance data DATA and outputs it as a start pulse SP out. The SP counter 62 may have, for example, a shift register that shifts the start pulse SP in synchronization with the clock CLK in order to delay the start pulse SP.

Using this setting, the LED driver 60A at the beginning of each row, that is, the enable signal ENB of the LED drivers 60A (1-1), 60A (2-1), ..., 60A (m-1) in the first column is output. Decide when to do it. For example, the count value of the LED driver 60A (1-1) is set to "1", and the count value of the LED driver 60A (2-1) is set to "2". In this case, when one start pulse SP is output, the LED driver 60A (1-1) outputs the start pulse SP as an enable signal ENB. When the first start pulse SP in the data column of the luminance data DATA in the second row is output to the second shot, the LED driver 60A (2-1) counts the two start pulse SPs, and as a result, the start pulse SP is output. Output as an enable signal ENB. In this way, the timing at which the leading LED driver 60A in the column direction outputs the enable signal ENB is controlled according to the count value of the number of pulses of the start pulse SP.

The set value is set by the LED drivers 60A (1-1) to 60A (m-1) at the head of each line connected to the second timing controller 22. The setting value of the other LED driver 60A is set to "1". This setting is realized by connecting to the power supply line and the ground line formed on the printed circuit board constituting the backlight panel 40. For example, when the count value of "1" is set to the above 3 bits, the 1st bit of the setting terminal is connected to the power supply line, and the 2nd and 3rd bits of the setting terminal are connected to the ground line.

The data latch circuit 63 is a circuit that samples the input serial luminance data DATA and converts it in parallel, and latches the converted parallel luminance data DATA. The data latch circuit 63 has an enable terminal EN, and when the enable signal ENB supplied from the SP counter 62 is received at the enable terminal EN, sampling of the luminance data DATA is started. For example, if the luminance data DATA is composed of 8 bits, the data latch circuit 63 acquires the 8-bit luminance data DATA by performing sampling eight times.

The start pulse output unit 64 outputs the start pulse SPout output from the SP counter 62 to the LED driver 60A in the next stage after the sampling of the data latch circuit 63 is completed. The start pulse output unit 64 is a buffer that amplifies the input start pulse SPout so that it is not output to the next stage in a attenuated state.

The clock output unit 65 is a buffer that amplifies the input clock CLK so that it is not output to the next stage in a attenuated state.

(Operation of LED driver 60A)
The operation of the first-stage LED driver 60A (1-1) and the second-stage LED driver 60A (1-2) in the first line will be described.

FIG. 4 is a timing chart showing the operation of the LED drivers 60A (1-1) and 60A (1-2).

As shown in FIG. 4, the luminance data DATA, the clock CLK, and the start pulse SP (SP1) are synchronously transmitted from the second timing controller 22. First, in the LED driver 60A (1-1), the SP counter 62 outputs the start pulse SP1 as the enable signal ENB because the count value obtained by counting the input start pulse SP1 becomes the set value “1”. do.

When the data latch circuit 63 receives the enable signal ENB (start pulse SP1), the data latch circuit 63 starts sampling the brightness data DATA, samples the input serial brightness data DATA (d0 to d7) bit by bit, and performs parallel. Convert to bit data D01 to D71. The data latch circuit 63 shifts the start pulse SP1 by an 8-bit shift register at the timing of the clock CLK to generate latch pulses D0 (Lat1) to D70 (Lat1). The data latch circuit 63 sequentially captures and holds bit data D01 to D71 bit by bit in synchronization with the latch pulses D0 (Lat1) to D70 (Lat1).

The SP counter 62 outputs the start pulse SPout at the next timing when the latch pulse D7 (Lat1) is output. The output of the start pulse SPout informs the LED driver 60A (1-2) of the next stage of the end of data sampling in the LED driver 60A (1-1).

In the LED driver 60A (1-2) of the next stage, when the start pulse SPout is input as the start pulse SP2, the SP counter 62 counts the start pulse SP2 as one set value, so that the start pulse SP2 Is output as the enable signal ENB.

When the data latch circuit 63 receives the enable signal ENB (start pulse SP2), the input serial brightness data DATA (d0 to d7) is sampled bit by bit and converted into parallel bit data D02 to D72. The data latch circuit 63 sequentially captures and holds bit data D02 to D72 bit by bit in synchronization with the latch pulses D0 (Lat2) to D70 (Lat2) generated based on the start pulse SP2.

In the LED drivers 60A (1-1) and 61A (1-2), the DA converter 61a generates an analog reference voltage Vref from the luminance data DATA acquired as described above. The operational amplifier 61b outputs a voltage corresponding to the difference between the terminal voltages of the operational amplifier 61b and the resistor 61d. As a result, the LED 50 is lit with the brightness defined by the luminance data DATA by supplying the drive current corresponding to the luminance data DATA by the transistor 61c.

As described above, by sequentially transmitting the start pulse SP between the cascade-connected LED drivers 60A, each LED driver 60A can sequentially capture the serial luminance data DATA. Therefore, in the backlight panel 40 in which a large number of LED drivers 60 are arranged, if the LED driver 60A is applied as the LED driver 60, the wiring formed on the backlight panel 40 can be reduced.

As shown in FIG. 4, between the final bit value d7 of the luminance data DATA and the first bit value d0 of the next luminance data DATA, there is an interval of one clock for the convenience of outputting the start pulse SPout. Need to be provided.

[Reference column 2]
(Configuration of LED driver 60B)
The LED driver of another reference example 2 will be described.

FIG. 5 is a circuit diagram showing the configuration of the LED driver 60B according to this reference example.

As shown in FIG. 5, the LED driver 60B according to this reference example includes an LED drive unit 61, a data latch circuit 63, a start pulse output unit 64, and a clock output unit 65, similarly to the LED driver 60A described above. Have. Further, the LED driver 60B has a CLK counter 66 instead of the SP counter 62 of the LED driver 60A.

The CLK counter 66 is a counter that counts the clock CLK. The CLK counter 66 outputs an enable signal ENB from the enable terminal EN when the count of the clock CLK is started and the count of a predetermined number of clocks is completed. The enable signal ENB is a signal required for the data latch circuit 63 to start data acquisition. The CLK counter 66 has a k-bit setting terminal for setting the order in which counting is enabled (setting value K). For example, when the set value K is 10 bits (k0 to k9) shown in FIG. 5, the order in which the 1024 (K = 1024) LED drivers 60B capture the luminance data DATA can be set.

(Operation of LED driver 60B)
The operation of the first-stage LED driver 60B (1-1) and the second-stage LED driver 60B (1-2) in the first line will be described.

FIG. 6 is a timing chart showing the operation of the LED drivers 60B (1-1) and 60B (1-2).

As shown in FIG. 6, in the LED driver 60B (1-1), the set value K is set to “0” at the setting terminal of the CLK counter 66, and in the LED driver 60B (1-2), the CLK counter 66. The setting value K is set to "1" at the setting terminal of.

The CLK counter 66 of the LED driver 60B (1-1) outputs an enable signal ENB that rises in synchronization with the rise of the first clock pulse in the clock CLK after reset.

The data latch circuit 63 sequentially performs 1 bit of bit data D01 to D71 converted in parallel with the brightness data DATA in synchronization with the latch pulses D0 (Lat1) to D70 (Lat1) generated between the eight clocks of the clock CLK. Take in and hold one by one. The data latch circuit 63 stops when the enable signal ENB falls.

In the LED driver 60B (1-2) of the next stage, the enable signal ENB of the CLK counter 66 having the set value K of "1" rises after 8 clocks of the clock CLK. The data latch circuit 63 sequentially captures and holds bit data D02 to D72 bit by bit in synchronization with the latch pulses D0 (Lat2) to D70 (Lat2) generated during the next eight clocks of the clock CLK. The data latch circuit 63 stops when the enable signal ENB falls.

In this way, each LED driver 60B can set the lighting brightness of the LED 50 to be driven by acquiring the brightness data DATA in the order determined by the set value K of the CLK counter 66.

Further, according to the LED driver 60B, the start pulse SP used in the LED driver 60A is not required. As a result, the number of wires between the second timing controller 22 and the LED driver 60B can be reduced, and connection problems due to signal delay in the cascade connection can be prevented. Further, since the start pulse SP is not used, it is not necessary to provide an interval for arranging the start pulse SP between the luminance data DATA (d0 to d7). Therefore, the speed of data transfer can be increased.

The LED driver 60B needs to reset the CLK counter 66 before starting the acquisition of the luminance data DATA. Therefore, the LED driver 66B includes a reset circuit (not shown).

As the reset circuit, for example, a power-on reset circuit that resets an internal circuit such as a latch in the LED driver 60B at the rise of the power supply is used. In addition, as the reset circuit, a reset circuit or the like is used in which the CLK counter 66 is reset when the luminance data DATA changes to Low, High, or Low while the clock CLK is fixed to Low. Alternatively, although the effect of reducing the number of wires cannot be obtained, a reset circuit for inputting a reset signal to the reset terminal of the CLK counter 66 may be provided.

[Embodiment 1]
The first embodiment of the present invention will be described with reference to FIGS. 7 and 8. In the present embodiment, the same reference numerals will be added to the components having the same functions as the components in Reference Examples 1 and 2 described above, and the description thereof will be omitted.

The LED drivers 60A and 60B of Reference Examples 1 and 2 described above capture the luminance data DATA while transferring it serially. However, as shown in FIGS. 3 and 5, the LED drivers 60A and 60B require a DA converter 61a and a data latch circuit 63. On the other hand, in the first to third embodiments, the LED driver 60 that does not use the DA converter 61a and the data latch circuit 63 will be described.

(Configuration of LED driver 60C)
FIG. 7 is a circuit diagram showing the configuration of the LED driver 60C according to the present embodiment.

As shown in FIG. 7, the LED driver 60C includes a clock output unit 65, a CLK counter 66, and an LED drive unit 70.

The LED drive unit 70 includes a switch control unit 71, switches 72 and 73, transistors 74 and 75, and a capacitor 76 (capacitive element). The transistors 74 and 75 and the capacitor 76 form an analog drive unit that supplies a drive current according to the luminance signal ADATA to the LED 50. The switch control unit 71 and the switches 72, 73 constitute a capture unit (capture unit, first capture unit) that captures the luminance signal ADATA in the order specified for the plurality of LED drivers 60C.

The switch control unit 71 gives the switches 72 and 73 an ON signal to turn on the switches 72 and 73 when the enable signal ENB output from the CLK counter 66 is High. The switch control unit 71 gives the switches 72 and 73 an OFF signal for turning off the switches 72 and 73 when the enable signal ENB output from the CLK counter 66 is Low.

The switch 72 opens and closes a path for transmitting an analog luminance signal ADATA (control information, analog signal) to the transistor 74. The luminance signal ADATA is a current or voltage signal representing the luminance obtained by converting the luminance data DATA into analog by a DA converter (not shown) provided in the second timing controller 22.

The gate and drain of the transistor 74 are connected, and the source of the transistor 74 is connected to the ground line. One end of the switch 73 is connected to the gate of the transistor 74, and the other end of the switch 73 and one end of the capacitor 76 are connected to the gate of the transistor 75 (drive transistor). The other end of the capacitor 76 is connected to the ground line.

The drain of the transistor 75 is connected to the cathode of the LED 50, and the source of the transistor 75 is connected to the ground line.

(Operation of LED driver 60C)
The operation of the first-stage LED driver 60C (1-1) and the second-stage LED driver 60C (1-2) in the first line will be described.

FIG. 8 is a timing chart showing the operation of the LED driver 60C.

As shown in FIG. 8, in the LED driver 60C (1-1), since the set value K of the CLK counter 66 is “0”, the count becomes valid during the first 8 clocks of the clock CLK, and is High. The enable signal ENB of is output. When the switch control unit 71 outputs an ON signal in response to the enable signal ENB, the switch 72 closes. Then, the luminance signal ADATA is taken into the inside of the LED driver 60C (1-1). Further, since the switch 73 is also closed, the transistors 74 and 75 form a current mirror circuit. Therefore, a drive current corresponding to the current flowing through the transistor 74 flows through the transistor 75. As a result, the LED 50 is lit with a brightness corresponding to the brightness signal ADATA.

The terminal voltage Vc of the capacitor 76 maintains a value corresponding to the luminance signal ADATA during the period when the enable signal ENB is High. Further, the capacitor 76 retains the above value even when the enable signal ENB changes to Low.

In the LED driver 60C (1-2), since the set value K of the CLK counter 66 is "1", the count becomes valid during the next 8 clocks of the clock CLK, and the High enable signal ENB is output. .. When the switch 72 is closed by the switch control unit 71, the luminance signal ADATA is taken into the LED driver 60C (1-2). Further, a drive current is supplied to the LED 50 through the current mirror circuits of the transistors 74 and 75 configured by closing the switch 73. As a result, the LED 50 is lit with a brightness corresponding to the brightness signal ADATA.

The capacitor 76 holds the value of the terminal voltage Vc during the period when the enable signal ENB is High even if the enable signal ENB changes to Low.

According to the LED driver 60C of the present embodiment, the DA converter 61a (see FIGS. 3 and 5) included in the LED drivers 60A and 60B of Reference Examples 1 and 2 is captured by capturing the luminance signal ADATA via the switch 72 in a time-division manner. ) Can be omitted. Therefore, by providing the DA converter in the second timing controller 22, it is possible to capture the luminance signal ADATA. Therefore, the cost of the image display device 1 can be significantly reduced.

Further, according to the LED driver 60C, the clock CLK is transmitted between the cascade-connected LED drivers 60C as in the LED driver 60B of Reference Example 2. As a result, each LED driver 60C can sequentially capture the luminance data ADATA. Therefore, the number of wirings formed on the backlight panel 40 can be reduced.

[Embodiment 2]
The second embodiment of the present invention will be described with reference to FIGS. 9 to 11 as follows. In the present embodiment, the same reference numerals will be added to the components having the same functions as the components in the above-mentioned Reference Examples 1 and 2 and the first embodiment, and the description thereof will be omitted.

(Configuration of LED driver 60D)
FIG. 9 is a circuit diagram showing the configuration of the LED driver 60D according to the present embodiment.

As shown in FIG. 9, the LED driver 60D includes an SP counter 62, a start pulse output unit 64, a clock output unit 65, and an LED drive unit 70.

The LED drive unit 80 includes an LED drive unit 70, an interface unit 81 (second intake unit, second holding unit), a PWM signal generation unit 82, a switch control unit 83, and a switch 84. .. The transistors 75 and 82, the capacitor 76, and the PWM signal generation unit 82 form a digital drive unit that supplies a drive current to the LED 50 according to the luminance data DATA.

In the interface unit 81, the luminance data DATA and the luminance signal ADATA are input to the data terminal D through the same signal line. The interface unit 81 operates at the timing of the clock CLK input to the clock terminal CK. The interface unit 81 operates during a period in which the high chip select signal CS from the SP counter 62 is input to the chip select terminal C.

When the luminance data DATA is input to the data terminal D, the interface unit 81 samples (captures) the luminance data DATA in the order specified for the plurality of LED drivers 60D and holds the luminance data DATA, and the PWM signal generation unit Send to 82. Further, the interface unit 81 outputs a first signal indicating that the luminance data DATA is input to the switch control unit 83 during the period during which the luminance data DATA is input. On the other hand, the interface unit 81 outputs a second signal indicating that the luminance signal ADATA is input to the switch control unit 83 during the period during which the luminance signal ADATA is input.

The PWM signal generation unit 82 generates a PWM signal based on the sampling data supplied from the interface unit 81.

The switch control unit 83 outputs an OFF signal that turns off the switches 72 and 73 when the first signal is input from the interface unit 81. Further, the switch control unit 83 outputs an ON signal for turning on the switches 72 and 73 when the second signal is input from the interface unit 81.

(Operation of LED driver 60D)
The operation of the first-stage LED driver 60D (1-1) and the second-stage LED driver 60D (1-2) in the first line will be described.

FIG. 10 is a timing chart showing the operation of the LED driver 60D.

As shown in FIG. 10, the luminance data DATA, the clock CLK, and the start pulse SP (SP1) are synchronously transmitted from the second timing controller 22. First, in the LED driver 60D (1-1), the SP counter 62 uses the start pulse SP1 as the chip select signal CS because the count value obtained by counting the input start pulse SP1 becomes the set value “1”. Output.

Upon receiving the chip select signal CS, the interface unit 81 samples the input serial brightness data DATA (d0 to d7) bit by bit in the same manner as the LED driver 60A of Reference Example 1, and parallel bit data D01 to D71. Convert to. The interface unit 81 shifts the start pulse SP1 by an 8-bit shift register at the timing of the clock CLK to generate latch pulses D0 (Lat1) to D70 (Lat1). The interface unit 81 sequentially captures and holds bit data D01 to D71 bit by bit in synchronization with the latch pulses D0 (Lat1) to D70 (Lat1), and sends the bit data D01 to D71 to the PWM signal generation unit 82 as sampling data.

The switch 84 opens and closes at a duty ratio determined by the PWM signal generated by the PWM signal generation unit 82 based on the sampling data. As a result, the LED 50 blinks when the drive current is intermittently supplied.

Further, the switch control unit 83 turns off the switch 72 when the first signal is given from the interface unit 81 during the period in which the luminance data DATA is input. As a result, the luminance data DATA is not input to the LED drive unit 70.

When the luminance signal ADATA is input following the luminance data DATA, the interface unit 81 gives a second signal to the switch control unit 83. Then, the switch control unit 83 turns on the switches 72 and 73. Further, the PWM signal generation unit 82 continuously opens and closes the switch 84 at a duty ratio determined by the PWM signal during a period in which sampling data is not input. As a result, the luminance signal ADATA is input to the LED drive unit 70, so that the LED drive unit 70 supplies the drive current to the LED 50. As a result, the LED 50 lights up.

The SP counter 62 outputs a start pulse SPout at the timing when the luminance signal ADATA (Analog) input following the luminance signal ADATA ends.

In the LED driver 60D (1-2) of the next stage, the SP counter 62 counts the start pulse SP2 (start pulse SPout), so that the start pulse SP2 is output as a chip select signal CS.

Upon receiving the chip select signal CS (start pulse SP2), the interface unit 81 samples the input serial luminance data DATA (d0 to d7) and converts them into parallel bit data D02 to D72. The interface unit 81 sequentially takes in bit data D02 to D72 and sends them to the PWM signal generation unit 82 in synchronization with the latch pulses D0 (Lat2) to D70 (Lat2) generated based on the start pulse SP2. Then, the LED 50 blinks when the switch 84 is opened and closed by the PWM signal generated by the PWM signal generation unit 82.

During the period in which the luminance signal ADATA is input following the luminance data DATA, the LED 50 is driven by the LED drive unit 70 as in the first stage LED driver 60D (1-1).

As described above, according to the LED driver 60D, by sequentially transmitting the start pulse SP between the cascade-connected LED drivers 60D, each LED driver 60D transmits the serial luminance data DATA and the analog luminance signal ADATA. It can be imported sequentially. Therefore, as with the LED driver 60A of Reference Example 1, the number of wirings formed on the backlight panel 40 can be reduced.

Further, in the LED driver 60D, the blinking time of the LED 50 is controlled by the PWM signal. As a result, for example, if the lighting and extinguishing are repeated at a ratio of 1: 7 at a speed that cannot be perceived by the human eye, the brightness can be reduced to 1/8.

As described above, the LED driver 60D controls the lighting of the LED 50 by combining the luminance data DATA and the luminance signal ADATA. In such a configuration, the brightness of the base that changes in a bright scene, a dark scene, or the like can be set based on the luminance signal ADATA, and further finer luminance can be set based on the luminance data DATA.

(Other operations of LED driver 60D)
Other operations of the first-stage LED driver 60D (1-1) and the second-stage LED driver 60D (1-2) in the first line will be described.

11 (a) and 11 (b) are timing charts showing other operations of the LED driver 60D.

The luminance data DATA is data for determining the duty ratio based on the above-mentioned PWM signal, and is frequently changed. On the other hand, the luminance signal ADATA is a signal for setting the drive current to be passed through the LED 50, and is hardly changed. However, although the drive current is hardly changed, in this drive method, the drive current is determined by the voltage held in the capacitor 76, so it is sometimes necessary to refresh the voltage held in the capacitor 76 by taking in the luminance signal ADATA. be.

Therefore, in this drive method, the luminance data DATA is rewritten many times, and the luminance data ADATA is rewritten from time to time.

As shown in FIG. 11A, a 1-bit flag (DorA) is provided between the end (d7) of the luminance data DATA and the beginning (d0) of the next luminance data DATA following it. .. This flag (DoA) is a flag indicating whether to capture the luminance data DATA or the luminance signal ADATA during the next data setting period, and is usually set to "0".

When the flag (DorA) is “0”, the interface unit 81 takes in the luminance data DATA (digital) at the timing of the next start pulse SP. Further, when the flag (DorA) is "1", the interface unit 81 gives a second signal to the switch control unit 83 so as to capture the luminance signal ADATA at the timing of the next start pulse SP. Based on such a flag setting, the luminance signal ADATA is rewritten repeatedly, and the luminance signal ADATA is intermittently written.

For example, when 10 LED drivers 60D are connected, the second timing controller 22 continues to send the luminance signal ADATA until all the luminance data DATA are written to these LED drivers 60D. Further, the second timing controller 22 rewrites the flag (DorA) to "1" at the timing when the voltage of the capacitor 76 should be refreshed while continuously transmitting the luminance data DATA. At this time, the second timing controller 22 rewrites all the flags (DorA) corresponding to the 10 LED drivers 60D to "1".

Thereby, the current value by the luminance signal ADATA can be set in the next data setting cycle. Specifically, each LED driver 60D is in a state of accepting the luminance signal ADATA (ON state of the switches 72 and 73) at the timing of the next start pulse SP, and refreshes the voltage of the capacitor 76.

The second timing controller 22 normally transmits the luminance data DATA in the data setting cycle following the data setting cycle in which the luminance signal ADATA is transmitted. Further, the second timing controller 22 returns the flag setting to "0" so that the luminance data DATA is automatically written in the data setting cycle next to the data setting cycle in which the luminance signal ADATA is written. In such control, it is complicated to send only one bit of luminance data DATA immediately after one LED driver 60D captures the luminance signal ADATA, and immediately after that, the next LED driver 60D captures the luminance signal ADATA. It is a control made from the fact.

As shown in FIG. 11A, in the connected LED drivers 60D (1-1), 60D (1-2), ..., Each interface unit 81 captures the luminance data DATA as described above. conduct. When each interface unit 81 recognizes that the flag provided following the captured luminance data DATA is “1”, it starts during the next data setting period as shown in FIG. 11 (b). The luminance signal ADATA (Analog) is taken in the period T1, T2, ... Specified by the pulses SP1, SP2, ...

According to the above operation, since the interface unit 81 takes in the luminance data DATA or the luminance signal ADATA according to the value of the flag, the switch control unit 83 can appropriately control the opening / closing operation of the switches 72 and 73. ..

[Embodiment 3]
The third embodiment of the present invention will be described with reference to FIGS. 12 to 15. In the present embodiment, the same reference numerals will be added to the components having the same functions as the components in the above-mentioned Reference Examples 1 and 2 and the first and second embodiments, and the description thereof will be omitted.

(First configuration of LED driver 60E)
FIG. 12 is a circuit diagram showing a first configuration of the LED driver 60E according to the present embodiment.

As shown in FIG. 12, the LED driver 60E includes an SP counter 62, a start pulse output unit 64, a clock output unit 65, and an LED drive unit 90.

The LED drive unit 90 includes an LED drive unit 80 and a current mirror circuit 91 (transmission blocking circuit).

The current mirror circuit 91 is connected to the connection point between the switch 73 and the capacitor 76 in the LED drive unit 80 and the gate of the transistor 75 in the LED drive unit 80.

In the LED driver 60D (see FIG. 9) described above, the drive current is set when the LED 50 is not lit, and when the capacitor 76 of the LED drive unit 80 holds the terminal voltage Vc, the drive current is passed through the LED 50. It will be in a non-existent state. In this state, the forward voltage Vf of the LED 50 is low. Therefore, the drain voltage of the transistor 75 when the terminal voltage Vc is held is a relatively high value.

Further, when the PWM signal generation unit 82 turns on the switch 84 to blink the LED 50, the forward voltage Vf of the LED 50 increases because the drive current flows through the LED 50, so that the drain voltage of the transistor 75 decreases. When the drain voltage drops, the terminal voltage Vc held by the capacitor 76 connected to the gate drops due to the influence of the parasitic capacitance between the gate and drain of the transistor 75. As a result, when the gate voltage drops, a current less than the set drive current flows through the LED 50.

Therefore, in the LED driver 60E, a current mirror circuit 91 is provided between the gate of the transistor 75 and the capacitor 76 so that the capacitance value of the capacitor 76 does not fluctuate due to the influence of the decrease in the gate voltage. By the current mirror circuit 91, the voltage due to the capacitance value of the capacitor 76 is transmitted to the gate, but the fluctuation of the gate voltage is not transmitted to the capacitor 76. As a result, the capacitance value of the capacitor 76 does not fluctuate under the influence of the decrease in the gate voltage.

(Second configuration of LED driver 60E)
FIG. 13 is a circuit diagram showing a second configuration of the LED driver 60E according to the present embodiment.

As shown in FIG. 13, the second configuration of the LED driver 60E includes the LED drive unit 90A instead of the LED drive unit 90 described above.

The LED drive unit 90A includes an LED drive unit 80 and a voltage follower 92 (transmission blocking circuit). The inverting input terminal of the voltage follower 92 is connected to the connection point between the switch 73 and the capacitor 76. Further, the output terminal of the voltage follower 92 is connected to the gate of the transistor 75 and the non-inverting input terminal of the voltage follower 92.

In the LED drive unit 90A configured as described above, the voltage follower 92 transmits the voltage due to the capacitance value of the capacitor 76 to the gate as in the current mirror circuit 91 (see FIG. 12) described above, but the fluctuation of the gate voltage. Is not transmitted to the capacitor 76. As a result, the capacitance value of the capacitor 76 does not fluctuate under the influence of the decrease in the gate voltage.

(Fourth configuration of LED driver 60E)
FIG. 14 is a circuit diagram showing a third configuration of the LED driver 60E according to the present embodiment.

As shown in FIG. 14, the third configuration of the LED driver 60E includes the LED drive unit 90B instead of the LED drive unit 90 described above.

The LED drive unit 90B includes an LED drive unit 90A and switches 93 and 94. The opening and closing of the switches 93 and 94 is controlled by the PWM signal generation unit 82. One end of the switch 93 is connected to the output terminal of the voltage follower 92, and the other end of the switch 93 is connected to the gate of the transistor 75. One end of the switch 94 is connected to the gate of the transistor 75, and the other end is connected to the ground line.

The switch 93 is controlled to be turned on when a drive current is passed through the LED 50, and is controlled to be turned off when a drive current is not passed through the LED 50. The switch 94 is controlled to be turned on when the drive current is not passed through the LED 50, and is controlled to be turned off when the drive current is passed through the LED 50.

In the LED drive unit 90B configured as described above, the switch 93 opens and closes at a duty ratio determined by the PWM signal generated by the PWM signal generation unit 82 based on the sampling data. As a result, the LED 50 blinks when the drive current is intermittently supplied. Further, since the switch 94 is turned on when the drive current is not passed through the LED 50, the electric charge accumulated in the gate of the transistor 75 is released to the ground line.

(Fourth configuration of LED driver 60E)
FIG. 15 is a circuit diagram showing a fourth configuration of the LED driver 60E according to the present embodiment.

As shown in FIG. 15, the fourth configuration of the LED driver 60E includes the LED drive unit 100 instead of the LED drive unit 90 described above.

The LED drive unit 100 includes an LED drive unit 90 and an operational amplifier 101. The non-inverting input terminal of the operational amplifier 101 is connected to the connection points of the two transistors 91a and 91b on the output side of the current mirror circuit 91. The inverting input terminal of the operational amplifier 101 is connected to the connection point between the transistor 75 and the switch 84. Further, the output terminal of the operational amplifier 101 is connected to the gate of the transistor 75 and the gate of the transistor 91b.

In the LED drive unit 100 configured as described above, the gate voltage of the transistor 75 can be increased to near the voltage of the power supply. As a result, the maximum capacity of the transistor 75 can be utilized. Therefore, by reducing the size of the transistor 75, the size of the chips constituting the LED drive unit 100 can be reduced. Therefore, the cost of the image display device 1 can be reduced.

[Embodiment 4]
The fourth embodiment of the present invention will be described with reference to FIGS. 16 and 17. In the present embodiment, the same reference numerals will be added to the components having the same functions as the components in the above-mentioned Reference Examples 1 and 2 and the first to third embodiments, and the description thereof will be omitted.

FIG. 16 is a diagram showing the configuration of the backlight panel 40A according to the present embodiment. FIG. 17 is a diagram showing a configuration of a backlight panel 40 according to a comparative example of the present embodiment.

In general, the emission brightness of the LED element changes depending on the temperature. Therefore, in order to control the lighting of the LED 50 so as to emit light at a desired brightness on the backlight panel 40, the temperature uniformity in the backlight panel 40 is required. In the backlight panel 40 (see FIG. 1) described above, the LEDs 50 are arranged substantially uniformly. As a result, the heat generated by the LED driver 60 arranged at the center of the four LEDs 50 can be uniformly distributed on the backlight panel 40.

However, the temperature distribution may not be uniform simply by arranging the LEDs 50 uniformly. In the backlight panel 40 as a comparative example shown in FIG. 17, the LED 50 arranged inside is affected by heat generated from the LED driver 60 from four directions. However, the LED 50 on the outer periphery arranged near the side edge of the backlight panel 40 is affected by heat generated by the LED driver 60 only from one direction or two directions. Therefore, the temperature of the outer peripheral portion of the backlight panel 40 is slightly lower than that of the inner portion. Therefore, in the backlight panel 40, the temperature distribution is not uniform.

In order to improve the non-uniformity of the temperature distribution, the backlight panel 40A according to the present embodiment is provided with a plurality of heat generating sources 5. The heat generation source 5 is a driver having the same structure as the LED driver 60 (hereinafter referred to as a dummy driver), or is a combination of a load resistance and a dummy driver that allows a current to flow through the load resistance. be. The heat generation source 5 is mounted on the same surface as the surface on which the LED 50 and the LED driver 60 are arranged in the backlight panel 40A. Further, the heat generation source 5 is arranged in the peripheral portion of the substrate 40a of the backlight panel 40A, more specifically, in the vicinity of the side edge of the substrate 40a.

The heat generation source 5 includes a dummy driver having the same structure as the LED driver 60. When such a heat generation source 5 passes a current having the same magnitude as the current of the LED driver 60, the influence of heat generation on the LED 50 is too large as compared with the LED driver 60.

For example, consider a case where the current of the LED driver 60 is 10 mA, the voltage of the anode of the LED 50 is 5 V, and the forward voltage VF of the LED 50 is 3 V. In this case, only the remaining 2V, which is 3V dropped by the LED 50 from 5V, is applied to the LED driver 60 to which the LED 50 is connected. Therefore, the amount of heat generated by the LED driver 60 is 20 (mW) (= 2 (V) × 10 (mA)).

On the other hand, when the dummy driver to which the LED 50 is not connected passes the same current as the LED driver 60, 5V is applied to the dummy driver, so that the amount of heat is 50 (mW) (= 5 (V) × 10 (mA)). It becomes.

Even when the load resistance is connected to the dummy driver to configure the heat generation source 5, if the resistance value of the load resistance is 200Ω, the remaining 3V dropped by 2V due to the load resistance is applied to the dummy driver. However, the load resistance generates 20 mW of heat, and the dummy driver generates 30 mW of heat. Therefore, if the combination of the dummy driver and the load resistance is used as the heat generation source 5, a total of 50 mW will be generated.

Further, since it is not possible to secure a large space for mounting the heat generation source 5 in the peripheral portion of the backlight panel 40A, the dummy driver used for the heat generation source 5 is the LED 50 as compared with the LED driver 60 to which the LED 50 is connected. It is placed a little closer. Therefore, even if the heat generation source 5 has the same amount of heat generation as the LED driver 60, the influence of heat generation on the nearest LED 50 becomes large.

Therefore, the heat generation source 5 causes a current smaller than the current that the LED driver 60 passes through the LED 50 as a reference. For example, the heat generation source 5 passes a current that is reduced by a constant ratio with respect to the current that the latest LED driver sends to the LED luminance control.

Here, the distance between the LED 50 arranged in the peripheral portion of the backlight panel 40A and the LED driver 60 arranged in the immediate vicinity of the LED 50 is defined as the first distance D1. Further, the distance between the LED 50 and the heat generating source 5 arranged in the immediate vicinity of the LED 50 is defined as the second distance D2. As the LED driver 60, any of the above-mentioned LED drivers 60C to 60E is used.

The current flowing through the heat generation source 5 is controlled by the second timing controller 22. Assuming that the current flowing through the LED 50 by the LED driver 60 is I1 and the current flowing through the heat generating source 5 is I2, the currents I1 and I2 are controlled so as to satisfy the relationship (I1 / M × I2) = D1 / D2. Here, M is the above-mentioned constant ratio and is a real number satisfying 0 <M <1. Therefore, the current I2 supplied to the heat generating source 5 is expressed by the following equation.

I2 = (D2 / M × D1) × I1
The LED 50 arranged inside the outer peripheral portion of the backlight panel 40A is affected by heat generated by the plurality of LEDs 50 arranged around the LED 50. On the other hand, in the LED 50 arranged in the peripheral portion, heat from the heat generating source 5 is given from the side edge of the backlight panel 40A by controlling the current flowing through the heat generating source 5 as described above. As a result, the LED 50 arranged in the peripheral portion is affected by the heat generated by the nearest LED driver 60 and the heat generating source 5 to the same extent as the heat generated by the inner LED 50 from the surrounding LED driver 60.

〔summary〕
The backlight device according to the first aspect of the present invention is driven by a substrate 40a, a plurality of LED drivers 60 arranged in a matrix on the substrate 40a, and the LED drivers 60, and is arranged around each LED driver 60. The plurality of LED elements (LED50) and the plurality of heat generating sources 5 arranged in the peripheral portion of the substrate 40a are provided.

According to the above configuration, the LED element arranged in the peripheral portion of the substrate is also heated by the heat generating source arranged in the peripheral portion of the substrate. As a result, the LED elements arranged in the peripheral portion of the substrate are affected by the heat from the surrounding LED drivers in the same manner as the LED elements arranged inside the substrate are affected by the heat from the surrounding LED drivers and the heat generating source. Affected by heat.

In the backlight device according to the second aspect of the present invention, in the first aspect, the LED driver 60 controls the current flowing through the LED elements arranged around the LED driver 60 to control the brightness of each LED element. The heat generating source 5 is an element that generates heat by flowing a flow, and a current may be passed based on the value of the current that the LED driver 60 closest to the heat generating source 5 flows through the LED element. ..

According to the above configuration, since the current flowing through the heat generation source is controlled with reference to the current flowing through the LED driver, it is possible to easily control the heat generation of the heat generation source.

In the backlight device according to the third aspect of the present invention, in the second aspect, the first distance between the LED element arranged in the peripheral portion of the substrate 40a and the nearest LED driver 60 is D1, and the LED element is the LED element. The second distance between the LED element and the heat generation source 5 closest to the LED element is D2, the current flowing through the LED driver 60 is I1, the current flowing through the heat generation source 5 is I2, and M is 0 <M <1. Assuming that the real number is satisfied, the relation I2 = (D2 / M × D1) × I1 may be satisfied.

According to the above configuration, when the heat generation source passes the same current as the LED driver and the heat generation amount becomes large, the heat generation amount of the heat generation source can be easily controlled based on the above equation.

In the backlight device according to the fourth aspect of the present invention, in any one of the first to third aspects, the heat generating source 5 may include a driver having the same structure as the LED driver 60.

According to the above configuration, the heat source can be manufactured by the same semiconductor process as the LED driver. As a result, it is not necessary to separately manufacture the heat generation source by a different manufacturing method. Therefore, the manufacturing cost of the backlight device can be reduced.

In the backlight device according to the fifth aspect of the present invention, in any one of the first to fourth aspects, the LED driver 60 is arranged at a position substantially equal to each of the plurality of the LED elements arranged around the LED driver 60. You may be.

According to the above configuration, one LED driver evenly affects the surrounding LED elements with heat generation. Thereby, the arrangement position of the heat generating source can be easily determined with reference to the arrangement position of the LED driver.

The display device according to the sixth aspect of the present invention includes a display panel 10 and a backlight device according to any one of the first to fifth aspects, which irradiates the display panel 10 with light from behind the display panel 10. There is.

[Additional notes]
The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and the embodiments obtained by appropriately combining the technical means disclosed in the different embodiments. Is also included in the technical scope of the present invention. Furthermore, new technical features can be formed by combining the technical means disclosed in each embodiment.

1 Video display device (display device)
5 Heat generation source 10 Display panel 22 Timing controller (backlight device)
40a board 50 LED (LED element)
60, 60C-60E LED driver D1 1st distance D2 2nd distance I1, I2 Current

Claims (6)

With the board
A plurality of LED drivers arranged in a matrix on the above substrate,
A plurality of LED elements driven by the above LED driver and arranged around each LED driver,
With a plurality of heat sources arranged around the substrate,
A backlight device characterized by being equipped with. The LED driver adjusts the brightness of each LED element by controlling the current flowing through the LED element arranged around the LED driver.
The heat source is an element that generates heat by passing a current, and the LED driver in the immediate vicinity of the heat source causes a current to flow based on the value of the current flowing through the LED element. The described backlight device. Let D1 be the first distance from the LED driver closest to the LED element arranged in the peripheral portion of the substrate.
Let D2 be the second distance between the LED element and the heat source closest to the LED element.
Let the current flowing through the LED driver be I1.
Let I2 be the current flowing through the heat source.
If M is a real number that satisfies 0 <M <1,
I2 = (D2 / M × D1) × I1
The backlight device according to claim 2, wherein the relationship is satisfied. The backlight device according to any one of claims 1 to 3, wherein the heat generation source includes a driver having the same structure as the LED driver. The backlight device according to any one of claims 1 to 4, wherein the LED driver is arranged at a position substantially equal to each of the plurality of LED elements arranged around the LED driver. .. Display panel and
A display device comprising the backlight device according to any one of claims 1 to 5, which irradiates the display panel with light from behind the display panel.

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