JP5644385B2 - Display device - Google Patents

Description

The present invention relates to a display equipment for adjusting the brightness of the display unit in accordance with the illuminance around the display device.

Patent Document 1 discloses a liquid crystal display device equipped with a dimming control device capable of controlling the brightness of a backlight of a display panel. In this liquid crystal display device, five optical sensors are provided around the display screen, and sampling values are obtained three times continuously for each optical sensor at a cycle of about 0.1 mS, and the threshold value of the comparator is changed to VPL2 → VPL1 → VPL0. 3 comparison results (H or L) are output from the comparator in comparison with three consecutive sampling values in the same photosensor while changing the time, and three comparison results ( H or L) is output, the three comparison results (H or L) of the outputs of the five optical sensors are determined by majority decision, the majority decision determination result is encoded, and the brightness of the backlight is controlled.
As described above, when the illuminance around the display screen changes for a short time, the detection signals change in accordance with the illuminance change in all five optical sensors, and the comparison results for the outputs of the five optical sensors all change. . Therefore, the majority decision result also changes, and the backlight is controlled to a brightness according to the illuminance change for a short time.

  The display device described in Patent Literature 2 detects a first external light sensor that detects an external light amount that is irradiated on the front side of the display unit, and an external light amount that is irradiated on the top surface side or the back surface side of the display unit. A second external light sensor and a microcomputer to which ambient information indicating ambient conditions is input are provided. The microcomputer controls the brightness of the screen of the display unit based on the external light amount from the first external light sensor, the external light amount from the second external light sensor, and the ambient information.

  The video display device described in Patent Document 3 is configured to detect ambient illuminance using a plurality of ambient illuminance sensors and adjust the brightness of the screen, and the output of some ambient illuminance sensors outputs other ambient illuminance. If it is different from the sensor output, it is determined which ambient illuminance sensor output reflects the brightness of the room, and the screen brightness is adjusted based on the determined ambient illuminance.

  In the reflective liquid crystal display device described in Patent Document 4, the display surface illuminance is detected by a plurality of optical sensors provided in the vicinity of the display surface, and the display surface illuminance is predetermined by the lighting control circuit based on the detection result. The light emission intensity of the front light is controlled so as to be the size.

JP 2007-199274 A JP 2010-91816 A JP 2007-310096 A Republished patent WO2003 / 050602

  In the techniques described in Patent Documents 1 to 4, when a short-term change occurs in the illuminance around the display device, a short-term change occurs in the display luminance.

  In view of the above, an object of the present invention is to suppress annoyance in which a short-term change in display luminance is caused by a short-term change in illuminance around the display device.

To achieve the above object, the present invention is for controlling a backlight, a first illuminance detection unit for detecting the illuminance of the external environment of the display device, the brightness of the light outputted from the backlight a display device and a control unit,
A first illuminance difference determination unit that detects illuminance at predetermined intervals by the first illuminance detection unit and determines a magnitude relationship between a first difference value representing a difference between two consecutive detected illuminances and a first threshold value. When,
A second illuminance difference for determining a magnitude relationship between a second difference value representing a difference between the maximum illuminance and the minimum illuminance among the illuminances detected by the first illuminance detection unit continuously a predetermined number of times. It has a judgment part ,
When the first difference value is equal to or greater than the first threshold value and the second difference value is equal to or less than the second threshold value , the control unit performs the backlight based on the illuminance detected by the first illuminance detection unit. The brightness of the light output from is changed .

According to the first , second, and seventh aspects of the invention, it is possible to suppress bothersomeness in which a short-term change in display luminance is caused by a short-term change in illuminance around the display device.
In the invention which concerns on Claim 6 , the troublesomeness which a short-term change arises in a display brightness | luminance by a short-term change in the illumination intensity around a display apparatus can be suppressed appropriately with a simple structure.
In the invention according to the third to fifth aspects, it is possible to more appropriately suppress the troublesomeness in which the short-term change in the display luminance is caused by the short-term change in the illuminance around the display device .

(A) is a front view schematically illustrating the configuration of a television (display device) 1 according to an embodiment of the present invention, and (b) is a side view schematically illustrating the configuration of the television 1. . 1 is a block diagram illustrating a circuit configuration of a television 1. FIG. (A) is a figure which illustrates the characteristic of the sensor voltage output with respect to ambient illuminance, (b) is a figure which illustrates the characteristic of the screen brightness | luminance L1 with respect to ambient illuminance. 3 is a diagram illustrating a structure of data stored in a RAM 113. FIG. 4 is a flowchart illustrating a backlight brightness correction process performed in the television 1. (A) is a diagram illustrating a change in ambient illuminance, (b) is a diagram illustrating a change in output voltage of the illuminance sensor, and (c) is a diagram illustrating a change in screen luminance L1. It is a flowchart which shows the backlight brightness correction process of the modification which made threshold value TH1 and TH2 into 0. It is a flowchart which shows the backlight brightness correction process of the modification using only the front side illumination intensity sensor 31. FIG. It is a flowchart which shows the backlight brightness correction process which concerns on a comparative example.

(1) Outline of television (display device):
A television (display device) 1 illustrated in FIGS. 1A, 1 </ b> B, and 2 is a thin display device that displays an image (image) on a liquid crystal panel 128 a serving as a display screen 10. Of course, the television to which the present invention can be applied may be a display such as a liquid crystal television, a thin display device such as a plasma television, a picture tube display device, and a television integrated with a recording / reproducing device. The recording / reproducing apparatus includes a hard disk recording / reproducing apparatus, a BD (Blue-ray Disc) recording / reproducing apparatus, a DVD (Digital Versatile Disk) recording / reproducing apparatus, a video deck, and the like. The display device also includes a display that does not receive a television broadcast.

A display device exemplified by the television (TV) 1 includes a display unit 2 for displaying an image, illuminance detection means 3 for detecting the illuminance around the display device, and the display unit 2 according to the detected illuminance. Brightness adjustment means 4 for adjusting the brightness L1 of the light source, and illuminance difference determination means 5 are provided.
The illuminance difference determining means 5 detects the illuminance by the illuminance detecting means 3 every predetermined period T, and the maximum illuminance EFmax of the detected illuminances EF0 to EF5 and EU0 to EU5 of the predetermined number N of times including the latest detected illuminances EF0 and EU0. , EUmax and the predetermined number N of detected illuminances EF0 to EF5, EU0 to EU5 minimum illuminances EFmin and EUmin (R1, R2) and a predetermined amount (TH1) are determined. The brightness adjusting means 4 adjusts the brightness L1 of the display unit 2 according to the detected illuminance when it is determined that the difference (R1, R2) is less than or less than the predetermined amount (TH1). When it is determined that R1, R2) is not less than or less than the predetermined amount (TH1), the luminance L1 of the display unit 2 is not changed.

  That is, the difference (R1, R2) between the maximum illuminance EFmax, EUmax and the minimum illuminance EFmin, EUmin selected from the detected illuminances EF0 to EF5, EU0 to EU5 of the predetermined number N of consecutive times including the latest detected illuminances EF0 and EU0 is small. The luminance L1 of the display unit 2 is adjusted according to the detected illuminance. If the difference (R1, R2) is large, the luminance L1 of the display unit 2 does not change. As a result, when the illuminance around the display device changes for a short time, the display brightness L1 does not change for a short time. Therefore, this display device can suppress the annoyance that a short-term change occurs in the display luminance L1 due to a short-term change in the illuminance around the display device.

  The predetermined amount may be a threshold value. Accordingly, the illuminance difference determining means 5 is configured to detect the maximum illuminances EFmax and EUmax of the detected illuminances EF0 to EF5 and EU0 to EU5 for a predetermined number N and the minimum illuminances EFmin and EUmin for the detected illuminances EF0 to EF5 and EU0 to EU5 for the predetermined number N. The magnitude relationship between the difference values R1 and R2 representing the difference between and a predetermined threshold value TH1 may be determined. The brightness adjusting means 4 adjusts the brightness L1 of the display unit 2 according to the detected illuminance when it is determined that the difference values R1 and R2 are less than or less than the threshold value TH1, while the difference values R1 and R2 If it is determined that is not less than or less than the threshold TH1, the luminance L1 of the display unit 2 may not be changed. Thereby, the troublesomeness which a short-term change in the display brightness | luminance L1 due to a short-term change in the illumination intensity around a display apparatus can be suppressed appropriately with a simple configuration.

Here, the difference value includes a difference (Emax−Emin) between a value Emax representing the maximum illuminance EFmax and EUmax and a value Emin representing the minimum illuminance EFmin and EUmin, a value obtained by converting this difference by a predetermined function, and a value Emax. , Emin ratio (Emax / Emin, etc.), a value obtained by converting this ratio with a predetermined function (1- (Emin / Emax)), a combination thereof, and the like. The values Emax and Emin may be the illuminance itself or values obtained by converting the illuminance by a predetermined function.
The predetermined number N is preferably 3 times or more, more preferably 4 times or more, and further preferably 5 times or more from the viewpoint of more reliably detecting a short-term change in illuminance.

  The illuminance difference determining means 5 is configured to detect a difference between the latest detected illuminances EF0 and EU0 and the detected illuminances EF1 and EU1 one time before the latest (single difference values DF1 and DU1) and the second place. When determining the magnitude relationship with the fixed amount (second threshold TH2) and determining that the one-time difference (one-time difference values DF1, DU1) is greater than or equal to the second predetermined amount (second threshold TH2) The predetermined illuminance N is detected by the illuminance detection means 3 every predetermined period T, and the maximum illuminance EFmax, EUmax of the predetermined illuminance EF0 to EF5, EU0 to EU5 and the predetermined illuminance EF0 of the predetermined number N are detected. While determining the magnitude relationship between the difference values R1, R2 representing the difference between the minimum illuminances EFmin, EUmin of EF5, EU0 to EU5 and the threshold value TH1, the one-time difference (one-time difference values DF1, DU1) is the second predetermined amount. (Second threshold TH2) or more or It may not perform a determination of the magnitude relationship between the difference value R1, R2 and the threshold value TH1 when it is judged not to be large Ri. At this time, when the brightness adjusting unit 4 determines that the one-time difference (one-time difference values DF1, DU1) is not greater than or equal to the second predetermined amount (second threshold value TH2), the luminance L1 of the display unit 2 is determined. It is not necessary to change.

  That is, a single difference (single difference) obtained from the two detected illuminances before judging the magnitude relationship between the difference values R1, R2 obtained from the detected illuminances EF0 to EF5, EU0 to EU5 a predetermined number N and the threshold value TH1. Since the magnitude relationship between the value DF1, DU1) and the second predetermined amount (second threshold value TH2) is judged, the judgment process of the magnitude relationship between the difference values R1, R2 and the threshold value TH1 is reduced, and the display brightness adjustment process is reduced. can do. Accordingly, it is possible to more appropriately suppress the annoyance of causing a short-term change in the display luminance L1 due to a short-term change in the illuminance around the display device.

The second predetermined amount may be a second threshold value TH2. Here, the second threshold value TH2 may be the same as the threshold value TH1, or may be a value different from the threshold value TH1.
The one-time difference value includes a difference (| E1-E0 |) between a value E0 representing the latest detected illuminance EF0, EU0 and a value E1 representing the previous detected illuminance EF1, EU1 (| E1-E0 |). The value converted by, the ratio of values E0 and E1 (E0 / E1 or E1 / E0), the value obtained by converting this ratio with a predetermined function (| (E0 / E1) -1 | etc.), a combination of these, etc. included. The values E0 and E1 may be the illuminance itself or values obtained by converting the illuminance by a predetermined function.

The illuminance detection means 3 may include a first illuminance detection means 3a and a second illuminance detection means 3b for detecting the illuminance at different positions.
At this time, the illuminance difference determining means 5 is configured such that the one-time difference value DF1 representing the difference between the detected illuminances EF0 to EF5 by the first illuminance detecting means 3a and the second threshold TH2 and the second illuminance. The magnitude relationship between the one-time difference value DU1 representing the difference between the detected illuminances EU0 to EU5 detected by the detection means 3b and the second threshold value TH2 is determined, and any one-time difference value DF1, DU1 is greater than or equal to the second threshold value TH2. When it is determined that the intensity is large, the predetermined number of times N, the first illuminance detection means 3a and the second illuminance detection means 3b detect the illuminance every predetermined period T, and the first illuminance detection means 3a The first illuminance EF0 to EF5 of the maximum illuminance EFmax and the predetermined illuminance EF0 to EF5 of the minimum illuminance EFmin representing the difference between the first difference value R1 and the threshold TH1 are determined, and the second illuminance is determined. Detection means For b, the magnitude relationship between the second difference value R2 representing the difference between the maximum illuminance EUmax of the predetermined illuminances EU0 to EU5 and the minimum illuminance EUmin of the predetermined illuminances EU0 to EU5 and the threshold TH1 is determined. On the other hand, when it is determined that one of the one-time difference values DF1, DU1 is not greater than or equal to the second threshold value TH2, the determination of the magnitude relationship between the first difference value R1 and the threshold value TH1, and the second difference It is not necessary to determine the magnitude relationship between the value R2 and the threshold value TH1.
At this time, the brightness adjusting unit 4 determines that the first illuminance detection unit 3a is determined when the first difference value R1 is equal to or less than the threshold value TH1 and the second difference value R2 is equal to or less than the threshold value TH1. While adjusting the luminance L1 of the display unit 2 according to the detected illuminance, it is determined that the first difference value R1 is not less than or less than the threshold value TH1, or the second difference value R2 is not less than or less than the threshold value TH1. If the luminance L1 of the display unit 2 is not changed, and if it is determined that one of the one-time difference values DF1, DU1 is not greater than or equal to the second threshold value TH2, the luminance L1 of the display unit 2 is It is not necessary to change.

  That is, since the second illuminance detecting means 3b is used in combination with the first illuminance detecting means 3a for obtaining the detected illuminance for adjusting the display brightness, the accuracy in determining whether or not to adjust the display brightness is improved. . Accordingly, it is possible to more appropriately suppress the annoyance of causing a short-term change in the display luminance L1 due to a short-term change in the illuminance around the display device.

The first illuminance detection means 3 a may include a front side illuminance sensor 31 that detects the illuminance on the front side of the display unit 2. The second illuminance detection means 3b may include an upper illuminance sensor 32 that detects the illuminance on the upper side of the display unit 2.
That is, the illuminance on the front side of the display unit 2 is set as the detected illuminance for adjusting the display luminance, and the detected illuminance is used together with the illuminance on the upper side of the display unit 2 to determine whether to adjust the display luminance. Accordingly, it is possible to more appropriately suppress the annoyance of causing a short-term change in the display luminance L1 due to a short-term change in the illuminance around the display device.

  The threshold value (predetermined amount) may be 0. Therefore, the illuminance difference determining means 5 may determine whether or not the detected illuminances EF0 to EF5 and EU0 to EU5 for the predetermined number N are all the same. The luminance adjusting means 4 adjusts the luminance L1 of the display unit 2 according to the detected illuminance when it is determined that the detected illuminances EF0 to EF5 and EU0 to EU5 are all the same N times. When the detected illuminances EF0 to EF5 and EU0 to EU5 for the predetermined number N are not all determined to be the same, the luminance L1 of the display unit 2 may not be changed. Thereby, the troublesomeness which a short-term change in the display brightness | luminance L1 due to a short-term change in the illumination intensity around a display apparatus can be suppressed appropriately with a simple configuration.

(2) Configuration of television (display device):
The TV 1 includes a cabinet 8, illuminance sensors 31 and 32, a microcomputer (microcomputer) 110, a nonvolatile memory 118, a main body side transmission / reception device 119, display means 121 to 128, an audio output unit 130, a remote control (remote control device) 9, and the like. It has. The cabinet 8 forming the television main body is formed in a substantially box shape with resin or the like, and has an opening for the display screen 10 on the front surface. The illuminance sensors 31 and 32 constituting the illuminance detection means 3 are attached to the cabinet 8. The microcomputer 110 controls video display and audio output. The nonvolatile memory 118 is composed of, for example, a nonvolatile semiconductor memory and holds various data. The nonvolatile memory 118 may be a magnetic disk such as a hard disk. The main body side transmission / reception device 119 can transmit and receive an infrared signal (wireless signal) to and from the remote controller 9. The electric circuit of the TV 1 other than the remote controller 9 is accommodated in the cabinet 8.
First, each part of the display means will be described.

  For example, the tuner circuit 121 is selected by a PLL (Phase Lock Loop) synthesizer tuning method under the control of the microcomputer 110, amplifies the television broadcast signal received from the antenna 122, and heterodyne the amplified signal. It is converted to an intermediate frequency signal by detection. Television broadcasting includes terrestrial digital broadcasting, BS (Broadcasting Satellite) broadcasting, CS (Communication Satellite) broadcasting, terrestrial analog broadcasting, and the like. The intermediate frequency amplifier circuit 123 receives the intermediate frequency signal from the tuner circuit 121, amplifies the intermediate frequency signal, and outputs the amplified signal to the video detection circuit 124. The video detection circuit 124 extracts the decoded video signal and the audio signal from the intermediate frequency signal input from the intermediate frequency amplification circuit 123. The decoded video signal includes a luminance signal, a carrier color signal, and a synchronization signal. An AGC (Automatic Gain Control) circuit 125 receives a synchronization signal from the video detection circuit 124, and an RF-AGC (Radio Frequency Automatic Gain Control) voltage and IF-AGC (Intermediate Frequency) corresponding to the magnitude of the synchronization signal. Automatic Gain Control) voltage is generated. The video signal processing unit 126 further amplifies the composite video signal, performs Y / C separation by the Y / C separation circuit 126a, outputs the luminance signal (Y) to the matrix circuit 126c, and carries the carrier color signal (C). Is output to the color demodulation circuit 126b, and a synchronization signal obtained by the synchronization separation is output to the microcomputer 110. The color demodulation circuit 126b demodulates the carrier color signal (C) input from the Y / C separation circuit 126a into an RY color difference signal and a BY color difference signal, and outputs them to the matrix circuit 126c. The matrix circuit 126c performs matrix conversion processing based on the input luminance signal (Y), RY color difference signal, and BY color difference signal to generate an RGB (Red-Green-Blue) signal. The liquid crystal driver 127 receives the RGB signal from the video signal processing unit 126, generates a drive signal for driving the liquid crystal module 128 according to the RGB signal, and outputs the drive signal to the liquid crystal module 128.

  The liquid crystal module 128 constituting the display unit 2 generates a high voltage from the liquid crystal panel 128a serving as the display screen 10, the backlight 128b that irradiates the liquid crystal panel 128a from the back, and the input power supply voltage, and supplies the high voltage to the backlight 128b. A backlight driving unit 128c. The liquid crystal module 128 receives a drive signal from the liquid crystal driver 127 and displays an image on the liquid crystal panel 128a while turning on the backlight 128b in accordance with the drive signal.

The backlight drive unit 128 c includes a PWM dimming circuit 128 d that generates a PWM (Pulse Width Modulation) signal having a duty ratio corresponding to a control signal from the microcomputer 110. The backlight drive unit 128c controls the brightness of the backlight 128b according to the duty ratio of the PWM signal. Specifically, the light emission of the backlight 128b is made brighter as the duty ratio of the PWM signal becomes larger, and the light emission of the backlight 128b is made darker as the duty ratio of the PWM signal becomes smaller. As a result, the brightness of the display screen 10 (display unit 2) is adjusted.
As described above, the microcomputer 110, the backlight 128b, and the backlight driving unit 128c constitute the luminance adjusting unit 4.

  The audio output unit 130 amplifies the audio signal input from the video detection circuit 124 and outputs audio corresponding to the audio signal from the speaker.

The microcomputer 110 includes a CPU (Central Processing Unit) 111, semiconductor memories 112 and 113, a clock circuit 114, an OSD (On-Screen Display) circuit 115, and an A / D (analog / digital) conversion circuit 116 connected to an internal bus. 117, I / O (input / output) circuit, and the like. The CPU 111 executes a television control program written in a ROM (Read Only Memory) 112 while using a RAM (Random Access Memory) 113 as a work area, and controls the overall operation of the TV 1. In the ROM 112, a plurality of programs for causing the computer to function as the TV 1 including the brightness adjusting unit 4 and the illuminance difference determining unit 5 are written. As shown in FIG. 4, the RAM 113 stores values representing the detected illuminances EF0 to EF5 and EU0 to EU5 for a predetermined number N of times including the latest detected illuminances EF0 and EU0. These values may be the illuminance itself or values obtained by converting the illuminance by a predetermined function. The clock circuit 114 can measure the current time, generate an interrupt signal at regular intervals, and output the interrupt signal to the CPU 111. The OSD circuit 115 generates a signal to be superimposed on the OSD screen and outputs it to the video signal processing unit 126. Illuminance sensors 31 and 32 are connected to the A / D conversion circuits 116 and 117.
As described above, the microcomputer 110 constitutes the luminance adjustment unit 4 and the illuminance difference determination unit 5.

The front side illuminance sensor 31 is an analog output illuminance sensor attached to the lower side of the display screen 10 on the front side of the cabinet 8, and a first illuminance detection means for detecting the illuminance on the front side of the display screen 10. 3a is comprised. The upper illuminance sensor 32 is an analog output illuminance sensor attached to the upper side of the cabinet 8, and constitutes second illuminance detection means 3 b for detecting the illuminance on the upper side of the display screen 10.
FIG. 3A illustrates the voltage output characteristics of the illuminance sensor with respect to the ambient illuminance. Here, the horizontal axis is the illuminance (lx), and the vertical axis is the voltage output (V) of the illuminance sensor. This illuminance sensor is an instantaneous (short-term) change in ambient illuminance between 0 and 200 lx, such as when a person or object crosses the TV 1 or when a user watching at a close distance moves. When this occurs, the voltage output fluctuates.

FIG. 3B illustrates the characteristic of the luminance L1 of the display screen 10 with respect to the ambient illuminance. Here, the horizontal axis is the illuminance (lx), and the vertical axis is the luminance L1 (cd / m ² ) of the display screen 10. If there is no short-term change in the ambient illuminance, the luminance L1 of the display screen 10 becomes a luminance that matches the ambient illuminance between about 0 to 200 lx.

Here, the backlight brightness correction processing according to the comparative example shown in FIG. 9 will be described. The TV that performs this processing is assumed to have an analog output illuminance sensor attached only to the front side of the cabinet. This process starts, for example, when the TV is turned on, and is performed in parallel with other processes by multitasking.
When the process is started, the TV microcomputer reads the digital value representing the detected illuminance from the illuminance sensor 16 times every 100 milliseconds and stores it in the RAM (step S902; hereinafter, description of “step” is omitted). In S904, an arithmetic average value of 16 consecutive detected illuminances (digital values) is calculated. The microcomputer generates a control signal for PWM correction of the brightness of the backlight according to the obtained average value, outputs the control signal to the PWM dimming circuit (S906), and returns to S902.

For example, it is assumed that the ambient illuminance changes from 200 lx to 100 lx for 1 second and then returns to 200 lx. When the ambient illuminance is 200 lx, the average value corresponds to 200 lx, and the backlight brightness corresponds to 200 lx. If the ambient illuminance is 100 lx for 16 seconds during the 16 periods, the average value is a value corresponding to (100 × 10 + 200 × 6) /16=137.5 lx, and the backlight brightness is 137.5 lx. It becomes. Of course, when the ambient illuminance returns to 200 lx, the average value also becomes a value corresponding to 200 lx, and the brightness of the backlight returns to the brightness corresponding to 200 lx. Therefore, when a short-term change occurs in the illuminance around the TV, a short-term change occurs in the brightness of the display screen. This makes the user looking at the display screen 10 feel bothered.
On the other hand, the TV 1 of the present embodiment does not perform screen brightness correction for instantaneous ambient illuminance change, but displays it with an appropriate screen brightness that matches the ambient illuminance that changes in a short period of time.

(3) Operation (operation) and effect of television (display device):
Next, the operation, action, and effect of the TV 1 will be described.
FIG. 5 illustrates a backlight brightness correction process performed by the TV 1 with a flowchart. This process starts, for example, when the TV is turned on, and is performed in parallel with other processes by multitasking. Here, the microcomputer 110 that performs the processes of S102 to S114 constitutes the illuminance difference determination means 5. In addition, the microcomputer 110 that performs the process of S116 constitutes the luminance adjusting unit 4 together with the backlight 128b and the backlight driving unit 128c.

  When the process is started, the microcomputer 110 reads a digital value corresponding to the detected illuminance from both the illuminance sensors 31 and 32 every T seconds, and stores it in the RAM 113 (S102). Thereby, the microcomputer 110 detects the illuminance by the illuminance sensors 31 and 32 every predetermined period T seconds. The detection interval T of illuminance is not particularly limited, but can be about 0.1 to 2 seconds (for example, 0.4 seconds). Referring to FIG. 4, the value representing the past detected illuminance stored in the RAM 113 is shifted forward one time, and the current detected illuminance is stored in the RAM 113 as the latest detected illuminances EF0 and EU0. A value representing the detected illuminance EFi, EUi (i is an integer of 1 to 4) i times before is stored in the RAM 113 as a value representing the detected illuminance i + 1 times before. Thereby, the new detected illuminances EFi and EUi (i is an integer of 1 to 5) before i times become the detected illuminance before iT seconds.

  In S104, it is determined whether or not the latest detected illuminance EF0 from the front-side illuminance sensor 31 has changed significantly compared to the previous detected illuminance EF1. For example, a one-time difference value DF1 = | EF1-EF0 | representing a difference between the detected illuminances EF0 and EF1 stored in the RAM 113 is obtained, and this one-time difference value DF1 and a second threshold value (second predetermined amount) TH2 (TH2 ≧ 0) is determined. The one-time difference value is preferably a value that increases as the difference between EF0 and EF1 increases, but may be a value that decreases as the difference between EF0 and EF1 increases. The second threshold value TH2 may be a threshold value TH1 for comparison with a difference value that represents a predetermined number N of detected illuminance fluctuations, or may be zero. When the difference value is an integer, TH2 may be about 1 or 2. When the possible range of the one-time difference value is 0 to DF1max (DF1max> 0), TH2 may be about 0.01 × DF1max to 0.1 × DF1max. In S104, when the one-time difference value DF1 is equal to or greater than the threshold value TH2, the process proceeds to S106, and when the one-time difference value DF1 is less than the threshold value TH2, the process returns to S102. Of course, in S104, when the once-difference value DF1 is larger than the threshold value TH2, the process proceeds to S106, and when the once-difference value DF1 is less than or equal to the threshold value TH2, the process may return to S102. When TH2 = 0, it may be determined whether DF1> TH2.

  When a change in the output voltage of the front side illuminance sensor 31 is detected, a comparison is made as to whether the same change has occurred in the output voltage of the upper illuminance sensor 32, and no output voltage change has occurred in the upper illuminance sensor 32. When the voltage change occurs only in the front side illuminance sensor 31, the backlight PWM correction is not performed, and the screen brightness immediately before the output voltage change is maintained. Therefore, in S106, it is determined whether or not the latest detected illuminance EU0 from the upper illuminance sensor 32 has changed significantly compared to the previous detected illuminance EU1. For example, a one-time difference value DU1 = | EU1-EU0 | representing the difference between the detected illuminances EU0 and EU1 stored in the RAM 113 is obtained, and the magnitude of the one-time difference value DU1 and the second threshold value TH2 (TH2 ≧ 0) is calculated. Determine the relationship. The single difference value is preferably a value that increases as the difference between EU0 and EU1 increases, but may be a value that decreases as the difference between EU0 and EU1 increases. The second threshold value TH2 may be a threshold value TH1 for comparison with a difference value that represents a predetermined number N of detected illuminance fluctuations, or may be zero. When the difference value is an integer, TH2 may be about 1 or 2. When the possible range of the one-time difference value is 0 to DU1max (DU1max> 0), TH2 may be about 0.01 × DU1max to 0.1 × DU1max. In S106, when the one-time difference value DU1 is greater than or equal to the threshold value TH2, the process proceeds to S108, and when the one-time difference value DU1 is less than the threshold value TH2, the process returns to S102. Of course, in S106, when the once-difference value DU1 is larger than the threshold value TH2, the process proceeds to S108, and when the once-difference value DU1 is less than or equal to the threshold value TH2, the process may return to S102. When TH2 = 0, it may be determined whether DF1> TH2.

When an output voltage change occurs in the illuminance sensors 31 and 32, the output voltage of the illuminance sensors 31 and 32 is read N times, for example, every 400 msec. Here, when all the values of the illuminance sensors 31 and 32 match N times, it is assumed that the ambient illuminance has changed, and the backlight PWM correction corresponding to the voltage is performed according to the output voltage of the front-side illuminance sensor 31. On the other hand, if the values of either of the illuminance sensors 31 and 32 do not match, it is determined that an instantaneous illuminance change has occurred, and the correction operation is not performed, and the screen brightness immediately before the output voltage change is maintained.
First, in S108, a digital value corresponding to the detected illuminance from both illuminance sensors 31, 32 is read N times every T seconds and stored in the RAM 113. Thereby, the microcomputer 110 detects the illuminance by the illuminance sensors 31 and 32 every predetermined period T when determining that any one-time difference values DF1 and DU1 are greater than or equal to the threshold value TH2 or greater (N). To do. The predetermined number N is not particularly limited, but may be six times, for example.

In S110, the first difference representing the difference between the maximum illuminance EFmax and the minimum illuminance EFmin, where the maximum illuminance is EFmax and the minimum illuminance is EFmin among the predetermined predetermined number N of detected illuminances EF0 to EF5 from the front-side illuminance sensor 31. The value R1 = EFmax−EFmin is calculated.
In S112, the second difference value representing the difference between the maximum illuminance EUmax and the minimum illuminance EUmin, where the maximum illuminance is EUmax and the minimum illuminance is EUmin among a predetermined number N of consecutive detected illuminances EU0 to EU5 from the upper illuminance sensor 32. R2 = EUmax−EUmin is calculated.
The difference values R1 and R2 are preferably values that increase as the difference between the maximum illuminance and the minimum illuminance increases, but may be values that decrease as the difference between the maximum illuminance and the minimum illuminance increases.

  In S114, the magnitude relation between the first difference value R1 and the threshold (predetermined amount) TH1 (TH1 ≧ 0) and the magnitude relation between the second difference value R2 and the threshold TH1 (TH1 ≧ 0) are determined. TH1 may be 0. When the difference value is an integer, TH1 may be about 1 or 2. When the possible range of the difference value is 0 to Rmax (Rmax> 0), TH2 may be about 0.01 × Rmax to 0.1 × Rmax. In S114, when the first difference value R1 is not more than the threshold value TH1 and the second difference value R2 is not more than the threshold value TH1, the process proceeds to S116, where the first difference value R1 is greater than the threshold value TH1 or the second difference value When the value R2 is larger than the threshold value TH1, the process returns to S102. Of course, in S114, if the first difference value R1 is less than the threshold value TH1 and the second difference value R2 is less than the threshold value TH1, the process proceeds to S116, and the first difference value R1 is equal to or greater than the threshold value TH1, or the second difference value. When R2 is greater than or equal to the threshold value TH1, the process may return to S102. When TH1 = 0, it may be determined whether R1 ≦ TH1 and R2 ≦ TH1.

In S116, a control signal for PWM correcting the brightness of the backlight 128b according to the detected illuminance from the front side illuminance sensor 31 is generated and output to the PWM dimming circuit 128d. The value corresponding to the detected illuminance for PWM correction can be a value representing the average of six consecutive detected illuminances EF0 to EF5, a value representing the latest detected illuminance EF0, or the like. The PWM dimming circuit 128d generates a PWM signal having a duty ratio according to the input control signal. The backlight drive unit 128c controls the brightness of the backlight 128b according to the duty ratio of the PWM signal. As a result, the brightness of the display screen 10 is adjusted.
Thereafter, the microcomputer 110 returns the process to S102.

FIG. 6A illustrates the change in illuminance on the front side and the upper side of the TV 1. Here, the vertical axis represents time (seconds), and the horizontal axis represents illuminance (lx). FIG. 6B illustrates a change in sensor output when the ambient illuminance change shown in FIG. 6A occurs. Here, the vertical axis represents time (seconds), and the horizontal axis represents the output voltage (V) of the illuminance sensors 31 and 32. FIG. 6C illustrates a change in the screen brightness L1. Here, the vertical axis represents time (seconds), and the horizontal axis represents the luminance L1 (cd / m ² ) of the display screen 10.
The predetermined period T is 0.4 seconds, the predetermined number N is 6 times, and the threshold values TH1 and TH2 are both values corresponding to the output voltage 0.1V of the illuminance sensors 31 and 32.

In the example of FIG. 6B, only the output voltage of the front side illuminance sensor 31 is lowered from about 2.7 V to about 1.7 V for a short period of 1.6 to 2.0 seconds. Conventionally, a digital value of about 1.7 V is used, and the brightness of the display screen is lowered for a short period. In the present TV1, since the output voltage of the upper illuminance sensor 32 has not decreased for 1.6 to 2.0 seconds, the condition is not satisfied in S106 in FIG. 5, and the PWM correction in S116 is not performed.
Further, the output voltage of the front side illuminance sensor 31 has dropped from about 2.7 V to about 2.0 V or less for a short period of 4.0 to 4.8 seconds. The output voltage of the upper illuminance sensor 32 also decreases from about 3.0 V to about 2.3 V or less for a short period of 4.0 to 4.8 seconds. In the present TV1, the conditions of S104 and S106 are both established at a time of 4.0 seconds, and the difference values R1 and R2 are obtained from the six consecutive output voltages from 4.4 to 6.4 seconds. The first difference value R1 from the front side illuminance sensor 31 corresponds to about 2.7-1.3V, and the second difference value R2 from the upper side illuminance sensor 32 corresponds to about 3.0-1.7V. Value. In this case, the condition is not satisfied in S114 of FIG. 5, and the PWM correction in S116 is not performed.

  On the other hand, the output voltage of the front side illuminance sensor 31 is constant at about 1.3 V after the time 6.8 seconds. The output voltage of the upper illuminance sensor 32 is also constant at about 1.7 V after the time 6.8 seconds. In the present TV1, the conditions of S104 and S106 are both established at the time of 6.8 seconds, and the difference values R1 and R2 are obtained from the six consecutive output voltages of 7.2 to 9.2 seconds. Since the output voltage of the illuminance sensors 31 and 32 has not changed for 7.2 to 9.2 seconds, the first difference value R1 from the front-side illuminance sensor 31 becomes 0, and the second difference from the upper illuminance sensor 32 The difference value R2 is also 0. In this case, the condition is satisfied in S114 of FIG. 5, and the PWM correction in S116 is performed.

As described above, the difference between the maximum illuminance EFmax and EUmax and the minimum illuminance EFmin and EUmin selected from the detected illuminances EF0 to EF5 and EU0 to EU5 of the predetermined number of times N including the latest detected illuminances EF0 and EU0 (R1, When R2) is small, the luminance L1 of the display unit 2 is adjusted according to the detected illuminance, and when the difference (R1, R2) is large, the luminance L1 of the display unit 2 does not change. As a result, the screen brightness does not change with respect to the instantaneous illuminance change (for example, within 2 seconds), and appropriate screen brightness is maintained, so that the user is not bothered. Therefore, this display device can suppress the annoyance that a short-term change occurs in the display luminance L1 due to a short-term change in the illuminance around the display device.
Further, since the illuminance in the upward direction is sensed from the TV 1, the screen luminance correction is not applied to the illuminance change only in the vicinity of the front side illuminance sensor 31. Also in this respect, the present display device can suppress the troublesomeness that the short-term change in the display luminance L1 occurs due to the short-term change in the illuminance around the display device.

(4) Modification:
When an LED display device that displays using a plurality of LEDs (light emitting diodes) is used, the brightness of the display screen can be adjusted by adjusting the light emission brightness of each LED.
The display device includes third, fourth, fifth,... Illuminance detection means for detecting illuminance at a position different from the first and second illuminance detection means described above. Also good. As for the backlight brightness correction process, for example, when the value representing the detected illuminance is greater than or equal to a threshold value or greater than the threshold value as in S104 and S106 for all illuminance detection means, the process after S108 is performed. Difference values R1, R2,..., Rn are calculated as in S110, S112, and whether all R1, R2,..., Rn are less than or less than the threshold value TH1 as in S114 for all illuminance detection means. Just judge.
When the difference between the maximum illuminance and the minimum illuminance is expressed as a ratio, the luminance of the display unit may be adjusted when the ratio is 1 or close to 1. For example, when the ratio is the ratio of the maximum illuminance Emax to the minimum illuminance Emin, the threshold TH1 is 1 <TH1 (for example, 1.01 <TH1 <2, 1.02 <TH1 <1.5, 1.1 <TH1 <1 .3), if it is determined whether or not the ratio Emax / Emin is equal to or less than the threshold value TH1, the magnitude relationship between the difference between the maximum illuminance and the minimum illuminance and the predetermined amount is determined.
The order of the steps of the above-described processing can be changed as appropriate. For example, the determination process of S106 may be performed before the determination process of S104 of FIG.

  FIG. 7 is a flowchart showing a backlight brightness correction process according to a modification in which both the threshold value (predetermined amount) TH1 and the second threshold value (second predetermined amount) TH2 are zero. In this flow, S104 is replaced with S122, S106 is replaced with S124, and S110 to S114 are replaced with S126, compared with the flow of FIG.

When the process is started, the microcomputer 110 reads a value corresponding to the detected illuminance from both the illuminance sensors 31 and 32 every T seconds, and stores it in the RAM 113 (S102). In S122, it is determined whether or not the latest detected illuminance EF0 from the front side illuminance sensor 31 has changed from the previous detected illuminance EF1. That is, TH2 = 0, and if EF0 ≠ EF1, the process proceeds to S124, and if EF0 = EF1, the process returns to S102. In S124, it is determined whether or not the latest detected illuminance EU0 from the upper illuminance sensor 32 has changed from the previous detected illuminance EU1. That is, TH2 = 0, and if EU0 ≠ EU1, the process proceeds to S108, and if EU0 = EU1, the process returns to S102. In S108, a value corresponding to the detected illuminance from both illuminance sensors 31, 32 is read N times every T seconds and stored in the RAM 113. In S126, whether or not the predetermined number N of detected illuminances EF0 to EF5 from the front side illuminance sensor 31 are all the same, and whether the predetermined number N of detected illuminances EU0 to EU5 from the upper illuminance sensor 32 are all the same. Judging. If the condition is satisfied, the process proceeds to S116, and if there is any mismatch in the detected illuminances EF0 to EF5, or if there is any mismatch in the detected illuminances EU0 to EU5, the process returns to S102.
From the above, it is possible to appropriately suppress annoyance that a short-term change in the display luminance L1 due to a short-term change in the illuminance around the display device can be appropriately suppressed with a simple configuration.

  Even if the upper illumination sensor 32 is not provided, the basic operation and effect of the present invention can be obtained. Furthermore, even if the determination process of S104, S106, S122, and S124 is not performed, the basic operation and effect of the present invention can be obtained. FIG. 8 is a flowchart showing a backlight brightness correction process with a simple configuration using only the front side illuminance sensor 31. Compared with the flow of FIG. 5, this flow does not include S104 to S108, and S112 to S114 are replaced with S132.

When the process is started, the microcomputer 110 reads a value corresponding to the detected illuminance from the front-side illuminance sensor 31 every T seconds, and stores it in the RAM 113 (S102). In S110, the difference value R1 representing the difference between the maximum illuminance EFmax and the minimum illuminance EFmin, where the maximum illuminance is EFmax and the minimum illuminance is EFmin among the predetermined number N of detected illuminances EF0 to EF5 continuously from the front-side illuminance sensor 31. = EFmax-EFmin is calculated. In S132, the magnitude relation between the difference value R1 and the threshold value (predetermined amount) TH1 (TH1 ≧ 0) is determined. In S132, when the difference value R1 is equal to or less than the threshold value TH1, the process proceeds to S116, and when the difference value R1 is greater than or equal to the threshold value TH1, the process returns to S102.
Also according to the above, it is possible to appropriately suppress the troublesomeness in which the short-term change in the display luminance L1 due to the short-term change in the illuminance around the display device.

  As described above, according to the present invention, it is possible to appropriately suppress troublesomeness in which a short-term change in display luminance is caused by a short-term change in illuminance around the display device, according to various aspects. A display device, a display method, a television, a television control method, a display program, a television control program, a computer-readable non-transmission medium storing these programs, and the like can be provided.

  In addition, the above-described basic operations and effects can be obtained even by an apparatus, system, method, and program that do not have the configuration requirements according to the dependent claims but only include the configuration requirements according to the independent claims.

Needless to say, the present invention is not limited to the above-described embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combinations and apply them. It is disclosed as.

1 ... Television (display device),
2 ... display unit, 3 ... illuminance detection means,
3a ... first illuminance detection means, 3b ... second illuminance detection means,
4 ... brightness adjustment means, 5 ... illuminance difference judgment means,
8 ... Cabinet, 9 ... Remote control device,
10 ... display screen,
31 ... Front side illuminance sensor, 32 ... Upper illuminance sensor,
EF0 to EF5: Front side detected illuminance, EU0 to EU5: Upper side detected illuminance.

Claims (7)

A display device comprising a backlight , a first illuminance detection unit for detecting the illuminance of an external environment of the display device , and a control unit for controlling the brightness of light output from the backlight. ,
A first illuminance difference determination unit that detects illuminance at predetermined intervals by the first illuminance detection unit and determines a magnitude relationship between a first difference value representing a difference between two consecutive detected illuminances and a first threshold value. When,
A second illuminance difference for determining a magnitude relationship between a second difference value representing a difference between the maximum illuminance and the minimum illuminance among the illuminances detected by the first illuminance detection unit continuously a predetermined number of times. It has a judgment part ,
When the first difference value is equal to or greater than the first threshold value and the second difference value is equal to or less than the second threshold value , the control unit performs the backlight based on the illuminance detected by the first illuminance detection unit. A display device characterized by changing the brightness of light output from the display.   The controller does not change the brightness of the light output from the backlight when the second difference value is greater than the second threshold value or the first difference value is less than the first threshold value. The display device according to claim 1. A second illuminance detector for detecting illuminance at a position different from the detection position of the first illuminance detector ;
The first illuminance difference determination unit is a third difference value that represents a magnitude relationship between the first difference value and the first threshold value , and a difference between two consecutive detected illuminances by the second illuminance detection unit. And the magnitude relationship between the first threshold value and the first threshold value ,
The control unit is detected by the first illuminance detection unit when both the first difference value and the third difference value are not less than the first threshold value and the second difference value is not more than the second threshold value. The display device according to claim 1, wherein the brightness of light output from the backlight is changed based on the illuminance .   The second illuminance difference determining unit determines a magnitude relationship between the second difference value and the second threshold value, and continuously out of the illuminance detected by the second illuminance detecting unit for the predetermined number of times. Determining a magnitude relationship between a fourth difference value representing a difference between the maximum illuminance and the minimum illuminance and the second threshold;
  The control unit determines whether the first difference value and the third difference value are equal to or greater than the first threshold value, and both the second difference value and the fourth difference value are equal to or less than the second threshold value. The display device according to claim 3, wherein brightness of light output from the backlight is changed based on illuminance detected for one illuminance detection unit. The first illuminance detection unit includes a front side illuminance sensor that detects illuminance on the front side of the display screen ,
The display device according to claim 3, wherein the second illuminance detection unit includes an upper illuminance sensor that detects illuminance on the upper side of the display screen . The second illuminance difference determining unit determines whether or not the predetermined number of detected illuminances are all the same,
Wherein the control unit, while changing the brightness of the light detection intensity of the predetermined number of times is output from the backlight based on the detected illuminance all be the same, the detection intensity of all the same the predetermined number of times The display device according to claim 1, wherein the brightness of light output from the backlight is not changed when it is not necessary.   The control unit changes the brightness of the light output from the backlight to an average corresponding to the predetermined number of detected illuminances or a brightness corresponding to the last detected illuminance of the predetermined number of times. The display apparatus as described in any one of Claims 1-6.

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