JP2016006454A - Backlight emission control method and projector presentation method and self-luminous video display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for properly performing backlight emission control, projector emission control, and self-luminous display control, for achieving dynamic image quality having high quality, easiness of viewing, and reduced visual fatigue on a display device such as a television.SOLUTION: Target data indicating how to display and emit light in which, change of rapid emission intensity is relaxed, is converted into pulse density modulation control data, thereby, use of a general light emission element driver circuit, or drive of a projector light source, or, direct drive of a self-luminous display element, implement the conversion of the target data.

Description

  The present invention relates to a backlight emission control method, a projector display method, and a self-luminous image display method with improved image display quality.

  Display on a liquid crystal display has been conventionally performed using a backlight that always emits light for continuous images of about 30 to 60 frames per second. In the display quality, the video quality deterioration due to the video blur caused by such a display method was remarkable. Therefore, particularly in recent liquid crystal televisions, there is a case in which a motion blur countermeasure is implemented by combining a method of blinking a backlight with a display from 120 frames to 240 frames per second using an interpolated image. In many cases, the backlight emits light by using a rectangular wave type light emission control using an LED with high time response (as in JP 2011-75800A). At that time, Jerkiness (defined in) ANSI T1.801.02-1996 as "Motion that was originally smooth and continuous is perceived as a series of distinct snapshots.") There are concerns about new issues such as visual quality degradation and visual fatigue due to screen flicker. On the other hand, photoreceptor cells are given a sudden light stimulus change as shown in the literature (Biological Psychology: An Introduction to Behavioral, Cognitive, and Clinical Neuroscience, Second Edition, Sinauer Association, 1999, p.226). It is known to cause bursty neural activity immediately after being given. Moreover, it is known that the human neural response is large immediately after receiving a stimulus as shown in the above-mentioned literature (p. 197) and gradually relaxes thereafter. In other words, since nerves are sensitive to sudden changes in stimulus, it is assumed that the change in stimulus is temporally smooth, in a living body, brings about a more gentle response near normal. In order to cope with the problem caused by the rapid change in light intensity, a device has been devised in which a certain function form is applied to the time characteristics of light emission (Japanese Patent No. 4337673). However, the light emission control method shown in the device is described mainly with respect to analog current control, and some implementations that may be realized by using PWM (Pulse Width Modulation) and PAM (Pulse Amplitude Modulation). There is only a description, and there is no specific description of such a digital light emission control method. In addition, when trying to realize light emission control by analog current control, for example, the LED light emitting element driver IC, the time response performance of the signal that can be received at the terminal that allows current control of the AN37011B (IP_REF terminal) is insufficient, during the frame period Therefore, it is necessary to develop an analog circuit having a new high-speed response, which makes it difficult to design a drive circuit and increases the cost. Therefore, it was necessary to devise a digital light emission control method that can be easily realized at low cost.

  Therefore, paying attention to the digital signal input that can be received with the general LED light emitting element driver IC as described above while having light speed response, it is blocked in the literature (Visual Information Handbook, Asakura Shoten, 2000, p. 219). As described in the law of, the integration of light stimuli presented within the integration time of about 20 milliseconds, that is, the time shorter than 20 milliseconds, and the literature (Mark F. Bear, Barry W Connors, Michael A. Paradiso: Neuroscience exploring the brain, Williams and Wilkins, pp. 245-246, 1996) In addition to this, we have devised a specific driving method using PDM (Pulse Density Modulation).

JP 2011-75800 A

Japanese Patent No. 4337673

  The problem to be solved is to appropriately perform backlight emission control, projector emission display control, and self-emission display control for the purpose of realizing high-quality, easy-to-see video quality with reduced visual fatigue in a display device such as a television. This is a point where an inexpensive and specific method has not been realized.

  The present invention provides a pulse density modulation (PDM) signal supplied to a backlight light emitting element or projector light emission so that light emission of a display device can be appropriately controlled for the purpose of improving moving image quality and improving visibility. The most important feature is that drive signals supplied to the display device or the self-luminous display device are appropriately generated and the display devices emit light. Here, the self-luminous display device is an organic EL display (http://en.wikipedia.org/wiki/organic electroluminescence), a Crystal LED display (http://en.wikipedia.org/wiki/Crystal_LED_Display), etc. The display device typified by 1 emits light.

  The backlight light emission control method, projector light emission display control method, and self light emission display control method according to the present invention reduce moving image quality deterioration called moving image blurring and jerkiness, and make visual fatigue easy to see due to light emission in which steep luminance changes are alleviated. There is an advantage that a small number of displays can be mounted using a general light emitting element driver circuit or directly driving a self light emitting display device, and such display performance can be improved at a low cost.

FIG. 1 is a block diagram showing an implementation method. (Example 1) FIG. 2 is a block diagram showing an implementation method. (Example 2) FIG. 3 is a block diagram showing the implementation method. (Example 3) FIG. 4 is an example of a light emission control signal showing an implementation method. (Common to Examples 1, 2, and 3) FIG. 5 is an example of a flowchart showing an implementation method. (In the case of Example 1)

  A method of emitting display light in which a sudden change in luminance is reduced is realized at low cost by using a general light emitting element driver circuit or directly driving a self light emitting display element.

  FIG. 1 is a block diagram of an embodiment of the apparatus of the present invention. 1 is a first-stage signal processing circuit such as video input and image quality, 2 is a digital waveform signal generation circuit and storage circuit, 3 is a remote control, 4 is an LED, etc. A light emitting element driving circuit, 5 is a backlight such as an LED, 6 is an LCD (liquid crystal display), 7 is a video signal supply circuit timing controller and an LCD driving circuit.

  The first-stage signal processing circuit 1 such as video input and image quality receives the video signal, performs signal processing relating to the image quality such as gamma correction, and sends a video synchronization signal to the digital waveform signal generation circuit and the storage circuit 2. The video signal and the synchronization signal are sent to the video signal supply circuit timing controller and the LCD drive circuit 7. The digital waveform signal generation circuit and the storage circuit 2 have a function of generating a waveform signal for causing the backlight to emit light in accordance with the received synchronization signal, and storing, selecting, and reading out the signal. Such a waveform signal is given by the remote control 3. In this example, the remote control 3 is implemented by a PC or the like. The LED light emitting element drive circuit 4 supplies the waveform signal received from 2 to the LED backlight 5 in synchronization with the LCD display timing driven by the light source 7 so as to emit light so as to match the LCD display.

  In the second embodiment shown in FIG. 2, the display unit constituted by the LCD and the backlight of the first embodiment shown in FIG. 1 is replaced with a projector. Here, 11 is a first-stage signal processing circuit such as video input and image quality, 12 is a digital waveform signal generation circuit and storage circuit, 13 is a remote control, 14 is a light source driving circuit, 15 is a light source lamp, and 16 is a video signal supply circuit timing controller. And a display device driving circuit, 17 a display device such as a reflective liquid crystal, and 18 an optical system for projection. By giving a change to the light emission intensity of the light source, the same effect as in the first embodiment is brought about.

  Example 3 of FIG. 3 is obtained by replacing the display unit constituted by the LCD and the backlight of Example 1 shown in FIG. 1 with a self-luminous display panel. Here, 21 is a first-stage signal processing circuit such as video input and image quality, 22 is a digital waveform signal generation circuit and storage circuit, 23 is a remote control, 24 is a display signal generation and drive circuit, 25 is a self-luminous display panel, and 26 is a video. It is a signal supply circuit timing controller. By giving a change in emission intensity to the light emitting element itself, the same effects as those of the first and second embodiments are brought about.

  The graph of FIG. 4 shows the relationship between time (step number) and emission intensity, which is common to Example 1, Example 2, and Example 3. Here, the horizontal axis represents time (step number), and the vertical axis represents emission intensity (unit is arbitrary). Reference numeral 31 denotes a target light emission intensity, and reference numeral 32 denotes pulse light emission data corresponding thereto.

  FIG. 5 is an example of a backlight control flowchart corresponding to the first embodiment, in which 41 is a block for defining a light emission profile for one frame period (function Ft of light emission intensity with respect to time t), and 42 is a time chart for the light emission profile. A block for quantizing the number of divisions N to obtain a light emission intensity digital value Vi (the subscript i is a step number), and 43 for dividing one frame period equally into D and sub-regions (numbers m, m = 0 to D-1). , A step number j (j = 0 to N / D-1) is defined, and N / D emission intensity digital values are added to obtain a subtotal Sm = Σ (Vj). 44 is a subtotal Sm in each of the subregions. Is a block that obtains the emission pulse generation ratio Prm = Sm / H for each small region as a numerical value obtained by dividing the light emission profile peak value H by 45. Is the operation to find the remainder of the division, (int Is a block that generates a 1-bit data string B for all areas such that 1 becomes 0 when an integer operation is established, and 46 is a control device such as a PC from binary to octal, etc. Is converted into a format that can be easily transmitted to the display and is transmitted to the backlight control circuit of the display. 47 is provided on the display side to divide the backlight into blocks corresponding to the display scan as required. Each block expands data into a bit string and assigns 1 and 0 to light emission on / off of each light emitting element for each frame to emit a backlight.

  Thus, by converting the change in emission intensity during the target frame period into a pulse emission density equivalent to the emission intensity per unit time obtained by dividing the frame period, a light emitting element driver of a general display device or the like A signal that matches the input characteristics of the light source or the light emitting element itself can be obtained.

  Since this pulse emission data is generated by time resolution such as dividing one frame period by 4096 as shown in this example, for example, when one frame period is 1/240 seconds, one step is microseconds. It becomes an order. The data of this light emission pulse may be a signal that changes smoothly as if it passed through a low-pass filter due to the time constant held by the drive circuit, but this is to obtain a smoother change in light emission intensity. Is advantageous. On the other hand, when the time resolution of the drive circuit is high, a low-pass filter may be added. In addition, as described above, the visual characteristics have an effect comparable to a low-pass filter of the order of milliseconds, so even if minute time fluctuations of the order of microseconds remain, they are averaged and perceived as a global intensity change. It is known. If one frame period is divided into millisecond units as a normal Japanese or American television system, that is, 1/60 second, the number of divisions is about 10, which is sufficiently fine and considering the maximum pulse driving frequency of a general driving circuit. The number of divisions is about 10,000.

  In addition, since the target change in the light emission intensity in the above is given to reduce the degradation of the moving image quality and provide an image that is easy to see and has little visual fatigue, it may be uniformly increased or decreased. In the example shown in FIG. 4, an exponential decrease is given to the fall of the light intensity. This is because it is generally known that human neural activity exhibits an exponential response to stimuli from the outside world. Therefore, it is affinity for humans to give exponential changes to stimuli themselves. However, the change in the emitted light intensity may be a change in a linear function.

  The procedure shown in the above flowchart is a method of averaging the density of pulse data obtained a plurality of times by arbitrarily shifting the section to be divided, and smooth pulse density change data can be obtained over the entire frame period.

  The procedure shown in the flowchart is the same as that in the second and third embodiments where the main light emission pulse density is calculated.

  Since the display quality of televisions, computer monitors, mobile displays, in-vehicle displays, advertising displays, medical displays, etc. can be improved, it can be widely applied.

1 First-stage signal processing circuit such as video input and image quality 2 Digital waveform signal generation circuit and memory circuit 3 Remote control 4 Light emitting element drive circuit such as LED 5 Backlight such as LED 6 LCD (Liquid Crystal Display)
7 video signal supply circuit timing controller and LCD drive circuit 11 video input and image quality first stage signal processing circuit 12 digital waveform signal generation circuit and storage circuit 13 remote control 14 light source drive circuit 15 light source lamp 16 video signal supply circuit timing controller and display device Drive circuit 17 Display device such as reflective liquid crystal 18 Optical system 21 First stage signal processing circuit such as video input and image quality 22 Digital waveform signal generation circuit and storage circuit 23 Remote control 24 Display signal generation and drive circuit 25 Self-luminous display panel 26 Video signal supply Circuit timing controller 31 Target emission intensity graph 32 Pulse emission graph 41 Block for defining an emission profile (a function Ft of emission intensity with respect to time t) for one frame period 42 Block that quantizes optical profile at time division number N and obtains light emission intensity digital value Vi (where subscript i represents the division step number (i = 0 to N-1))
43 Equally divide one frame period into D and define step number j (j = 0 to N / D-1) in each of the small areas (number m, m = 0 to D-1) A block for obtaining a subtotal Sm = Σ (Vj) by adding the light emission intensity digital value 44 In each of the above small areas, the subtotal Sm is divided by the light emission profile peak value H. 45 A block that generates a 1-bit data string B for all the areas such that 1 when j% (int) (1.0 / Prm) = 0 is satisfied in each of the above small areas, and 0 otherwise. % Is an operation to find the remainder of division, and (int) is an integer operation)
46 A block that converts the data B into a format that can be easily transmitted by a control device such as a PC from binary to octal, etc., and transmits it to the backlight control circuit of the display. 47 A block that illuminates the backlight by preparing a block division of the light, expanding the data into a bit string for the entire backlight or for each block, and assigning 1 and 0 to light emission on / off of each light emitting element for each frame

Claims (16)

  A display characterized in that driving for increasing or decreasing the display light intensity at time t (0 <t <= T) in one display frame period T is realized by a change in display light intensity for each section obtained by dividing the display frame period. apparatus.   2. A display device according to claim 1, wherein the function for increasing or decreasing the display light intensity is an exponential function.   2. A display device according to claim 1, wherein the number of divisions of the display light intensity change for driving to increase or decrease the display light intensity at time t (0 <t <= T) in one display frame period T is 10 to 10,000.   3. The display device according to claim 2, wherein the number of divisions of the change in display light intensity for driving to increase or decrease the display light intensity at time t (0 <t <= T) in one display frame period T is 10 to 10,000.   A display device that realizes the display device according to claim 1 by changing a light emission intensity of a backlight of the LCD display device.   A display device that realizes the display device according to claim 2 by a change in emission intensity of a backlight of the LCD display device.   A display device that realizes the display device according to claim 3 by a change in emission intensity of a backlight of the LCD display device.   A display device that realizes the display device according to claim 4 by a change in emission intensity of a backlight of the LCD display device.   A display device that realizes the display device according to claim 1 by a change in light source emission intensity of the projector display device.   A display device that realizes the display device according to claim 2 by a change in light source emission intensity of the projector display device.   A display device that realizes the display device according to claim 3 by a change in light source emission intensity of the projector display device.   A display device that realizes the display device according to claim 4 by a change in light source emission intensity of the projector display device.   A display device that realizes the display device according to claim 1 by a method of directly driving the light emission intensity of the self-luminous display device.   A display device that realizes the display device of claim 2 by a method of directly driving the light emission intensity of the self-luminous display device.   A display device that realizes the display device according to claim 3 by a method of directly driving the light emission intensity of the self-luminous display device.   A display device that realizes the display device according to claim 4 by a method of directly driving the light emission intensity of the self-luminous display device.