The present application claims priority under 35 U. S. C. § 119 to Japanese Patent Application No. 2016-247763, filed Dec. 21, 2016. The contents of this application are incorporated herein by reference in their entirety.
The present disclosure relates to a display apparatus having a plurality of light emitting elements arranged in rows and columns.
Nowadays, a display unit using light emitting diodes (LEDs) as light emitting elements and a display apparatus using the display unit are manufactured. For example, a large-screen display apparatus can be made by combining a plurality of display units. In a display unit including LEDs arranged in a dot matrix array of m rows and n columns, for example, anode terminals of LEDs located at each row are electrically connected to a single common line and cathode terminals of LEDs located at each column are electrically connected to a single drive line. The common lines of m-rows are successively turned ON with a predetermined cycle and the LEDs arranged on the turned ON common lines are individually driven by the drive lines.
In a known method, gradation control of such a display apparatus is operated through turning on and off a plurality of light emitting elements by weighting lighting periods to power of two such as 1:2:4:8 (for example, see Japanese Unexamined Patent Application Publication No. 2005-010741). Such a control method may be referred to as “weighting control.”
However, in a conventional weighting control, positions to be lit are determined based on weighting arrangement, so that when the last weighted element in a timeline is turned on, significant pseudo lighting may be caused. Pseudo lighting may also be called erroneous lighting, false lighting, feeble lighting, or the like, and is typically referred to as unintended lighting caused by accumulated electric charges in a parasitic capacitance of a wiring.
There is a need to provide a display apparatus in which erroneous lighting of light emitting elements is reduced and display quality is improved.
A display apparatus includes a plurality of common lines, a plurality of drive lines, a plurality of light emitting elements respectively electrically connected to one of the plurality of common lines and one of the plurality of drive lines, a scanner to time-divisionally apply a voltage on the plurality of common lines, a driver to draw electric current at a predetermined timing from drive lines, of the plurality of drive lines, electrically connected to respective light emitting elements, of the plurality of light emitting elements, to turn ON the respective light emitting elements, and a lighting controller to vary lighting periods of the plurality of light emitting elements to express lighting amounts as different gradation values. A single frame is divided into a plurality of sub-frames and a gradation value to express in the single frame is divided into gradation values and allocated to the plurality of sub-frames, the gradation values allocated to the sub-frames are time-divisionally expressed so that the gradation value of the single frame is expressed by a total of the gradation values of the sub-frames. Each of the plurality of sub-frames includes a plurality of weighted elements with different gradation values to express the gradation values by powers of two, and a weighted element at an end of a timeline of a single sub-frame is assigned with a maximum gradation value. When the single frame includes X sub-frames (where X is an integer greater than 1), a maximum gradation value that can be expressed by each of the sub-frames is 2Y−1 (where Y is an integer greater than 1), and when the single frame is to express a gradation value in a range of X 2Y-1 to X(2Y−1)−2Y-1, the lighting controller allocates the gradation value to each of the sub-frames so that the weighted element at the end of the timeline of at least one sub-frame of the plurality of sub-frames in the single frame is turned OFF.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
The embodiments according to the present invention will be described below with reference to the drawings. The embodiments shown below are intended as illustrative to give a concrete form to technical ideas of the present invention, and the scope of the invention is not limited to those described below. Further, the members shown in claims attached hereto are not specifically limited to members in the embodiments. The sizes, materials, shapes and the relative configuration etc. of members described in embodiments are given as an example and not as a limitation to the scope of the invention unless specifically described otherwise. The sizes and the arrangement relationships of the members in each of drawings are occasionally shown exaggerated for ease of explanation. In the description below, the same designations or the same reference numerals denote the same or like members and duplicative descriptions will be appropriately omitted. In addition, a plurality of structural elements of the present invention may be configured as a single part which serves the purpose of a plurality of elements, on the other hand, a single structural element may be configured as a plurality of parts which serve the purpose of a single element. Description given in one example and one embodiment can also be applied in other examples and embodiments.
In the present specification, the term “parasitic capacitance” mainly refers to a parasitic capacitance in drive lines. Parasitic capacitance may exist between parts of electronic components, for example, caused by an electronic component having a capacitance connected to a drive line.
The plurality of light emitting elements are electrically connected to a plurality of common lines and a plurality of drive lines. In the present embodiment, light emitting diodes (LEDs) are used as the light emitting elements. The plurality of light emitting elements are arranged in rows and columns and respectively electrically connected to one of the plurality of common lines and one of the plurality of drive lines to form the display 10.
The scanner 20 time-divisionally applies voltage to the plurality of common lines and includes one or more source drivers. Further, an electric power source 60 is electrically connected to the scanner 20 to supply electric power to driver elements such as transistor that form the scanner 20. In the example shown in
The driver 30 draws electric current at predetermined timings from the drive lines electrically connected to the light emitting elements to light, and includes one or more sink drivers.
The lighting controller 50 controls those operations of the scanner 20 and the driver 30. An example of functional block diagram of the lighting controller 50 is illustrated in
The input unit 51 receives data to be displayed from an external display source, for example. The lighting control data generator 52 generates lighting control data according to the display data that is received, to drive the scanner 20 and the driver 30. The gradation allocator 53 allocates gradations to the sub-frames, as described below, to express gradations. The lighting control data generator 52 produces lighting control data by allocating gradations determined by the gradation allocator 53 to the sub-frames. The setting storage 54 stores setting data such as number of gradations to allocate to the sub-frames by the gradation allocator 53. The setting storage 54 may use a storage medium and a non-volatile memory. The output circuit 55 operates the scanner 20 and the driver 30 to activate corresponding light emitting elements according to the lighting control data generated by the lighting control data generator 52. One image expressed on the display 10 is expressed by one cycle a combination of a plurality of single frames each obtained by a single scan the scanner 20 scanned the common lines.
In order to express a multi-gradation color image, a single frame is divided into a plurality of sub-frames, gradation to be expressed in a single frame is divided and allocated through the sub-frames so that gradation allocated to each of the sub-frames is expressed in a time-sharing manner in operation. The allocation is provided by the gradation allocator 53. Thus, the gradation of a single frame is expressed with entire gradations of the sub-frames that form a single frame.
Each of the plurality of sub-frames is divided into a plurality of weighted elements each exhibiting different gradation based on powers of two. Further, the weighted element at the end of a timeline in each single sub-frame is designated to exhibit a greatest gradation. When the number of sub-frames in a single frame is X (X is an integer greater than 1) and a greatest gradation value that can be exhibited in each of the sub-frames is 2Y-1 (Y is an integer greater than 1), and the gradation value expressed in a single frame is between X·2Y-1 and X(2Y−1)−2Y-1, the lighting controller 50 allocates gradation values to the sub-frames so that in at least one sub-frame in the single frame, the weighted element at the end of the timeline of the single sub-frames is set to turn OFF its corresponding light emitting element.
Such a control of the gradation allocation in a gradation range described above is exercised because when the gradation value that is expressed in a single frame is smaller than X·2Y-1, the weighted element at the end of the timeline in a single sub-frame is OFF, which reduces pseudo lighting. Meanwhile, when the gradation value that is expressed in a single frame is greater than X(2Y−1)−2Y-1, the weighted element at the end of the timeline in each of the plurality of single sub-frames in a single frame is needed to be ON, so that the weighted element at the end of the timeline in a single sub-frame is not allowed to turn OFF.
In the first embodiment, when each of the sub-frames can express gradations of Y bits that is 2Y, a gradation value less than 2Y-1 is allocated to at least one sub-frame. For example, when each of the sub-frames can express a maximum gradation value of 32, at least one sub-frame is allocated to a gradation value of less than 16. In order to allocate gradations in one frame so that the last weighted element that is located at an end of timeline of at least one sub-frame is turned OFF, allocation of 16 or greater gradation values to all the sub-frames has to be avoided. This is because if all the sub-frames in a single frame are allocated to 16 or greater gradation values, the last weighted element with a gradation value of 16 is inevitably turned ON.
Gradation values are preferably allocated to the sub-frames respectively to increase the number of sub-frames to turn OFF the light emitting elements corresponding to the last weighted elements in the timelines in the weighting alignment in each of the sub-frames. For example, the lighting controller 50 operates so that, in at least half among the plurality of sub-frames in a single frame, the light emitting elements corresponding to the last weighted element in the timeline in a single sub-frame are turned OFF. Accordingly, pseudo lighting can be efficiently decreased.
It is more preferable that the lighting controller 50 allocates gradation values to the sub-frames so that a difference between the maximum value and the minimum value of gradation in each of the sub-frames to be two or greater. With this, allocation of gradation within the sub-frame can differ among the sub-frames that can facilitate to turn OFF the light emitting elements corresponding to the last weighted elements in the timeline in the sub-frames.
Further, difference in gradation value between adjacent two sub-frames of the plurality of sub-frames in a single frame is preferably 2Y-1+1. Accordingly, lighting control can be simplified. For example, monitoring two high-order bits in the gradation expressed in a single frame and when the two high-order bits are 10 (binary digits), gradation value of 2Y-2 may be added to one single sub-frame and gradation value of 2Y-2 may be subtracted from the other single sub-frame.
In addition, when the lighting controller 50 aligns the plurality of sub-frames, the weighted elements in each sub-frame are preferably aligned to increase the gradation values along the timeline. That is, the weighted elements of power of two in each sub-frame are aligned in ascending order.
When the lighting controller 50 aligns the plurality of sub-frames, the weighted element at the end in timeline of each of the sub-frames is allocated to the period of turning corresponding light emitting elements OFF, if the duration of the OFF period is short, an effect of pseudo lighting reduction may become difficult to exert. In order to efficiently exert such a pseudo lighting reduction effect, a single sub-frame necessarily includes an OFF period with a certain length. In the first embodiment, the weighted element at the end in the timeline of a single sub-frame has a maximum gradation value and the gradation value is allocated so that the weighted element of the maximum gradation value is to be turned OFF. Thus, the effect of pseudo lighting reduction can be efficiently exerted. Note that, if the light emitting elements corresponding to all weighted elements in a single sub-frame are to be turned off, the effect of pseudo lighting reduction may be exerted efficiently, however, generation of flickering may become of concern.
In the display apparatus 100 according to the first embodiment, gradation value is allocated to the sub-frames to reduce the number of light emitting elements turned on at the end in timeline in weighted alignment. That is, in a single frame, the sub-frames are allocated to gradation values so that the end weighted element in a timeline in a single sub-frame is OFF in at least one sub-frame in a single frame. Thus, reducing the number of lighting at the ends in timelines of a single sub-frame allows to provide a charging time for a parasitic capacitance between the drive line and the GND, through the light emitting element that is subjected to lighting. This can reduce the charging amount for the parasitic capacitance between the drive line and the GND, through the light emitting elements that are not subjected to lighting.
Example of Operation
Next, operation of a display apparatus 100 shown in
LEDs 1 to 9
As the plurality of light emitting elements, for example the plurality of LEDs 1 to 9 shown in
Common Lines COM1 to COM3
The common lines COM1 to COM3 are electrically connected to one ends of the plurality of LEDs 1 to 9. The plurality of LEDs 1 to 9 are connected to the common lines COM1 to COM3 in a common anode configuration as shown in
Power Supply 60
The power supply 60 applies voltage to the plurality of LEDs 1 to 9. The power source 60 applies voltages in a time-sharing manner to each common line (dynamic control). For the power supply 60, for example, a DC constant voltage source of a series system or a switching system can be employed.
Source Drivers SW11 to SW13
The source drivers SW11 to SW13 of the scanner 20 are switches for connecting the common lines COM1 to COM 3 and are time-divisionally turned ON or OFF by the lighting controller 50. For the source drivers SW11 to SW13, a P-channel field effect transistor (FET) or a PNP transistor can be used.
Drive Lines SEG1 to SEG3
The plurality of drive lines SEG1 to SEG3 are connected to other ends of the plurality of LEDs 1 to 9. For the drive lines SEG1 to SEG3, a copper foil or the like (e.g., part of the interconnection of the printed circuit board) may be employed.
Sink Drivers SW1 to SW23
Sink drivers SW21 to SW23 of the driver 30 are connected to a plurality of drive lines SEG1 to SEG3 and serve as switches connecting the drive lines SEG1 to SEG3 and GND, and are turned ON or OFF by the lighting controller 50. For the sink drivers SW21 to SW23, an NPN transistor or an N-channel field effect transistor (FET) can be used. The electric current flowing to the drive lines SEG1 to SEG3 can be controlled with a resistor and/or by a constant current source, or the like, which may be disposed between the sink drivers SW21 to SW23 and the GND, or between the sink drivers SW21 to SW23 and drive lines SEG1 to SEG3.
Lighting Controller 50
The lighting controller 50 controls ON or OFF of the source drivers SW11 to SW13 and the sink drivers SW21 to SW23, to control lighting of the plurality of LEDs. For example, when the LED 5 is lit, the SW12 and the SW22 are turned ON to apply voltage to allow an electric current flowing in a path: voltage V—>>common line COM2—>>LED5—>>drive line SEG2—>>GND, and the LED 5 is turned on.
Frame
A frame is a unit of an image displayed on a screen of the display apparatus 100, and includes at least one sub-frame. A method of displaying a single frame in multi-gradation with a plurality of sub-frames can be referred to as a sub-frame modulation.
Sub-Frame
A sub-frame is a unit of executing a scan through common lines, in which weighting control is applied to each of the common lines to express multiple gradations.
Display 10
Next, a reduction in pseudo lighting of a light emitting element will be illustrated with reference to
Comparative Example
In the example shown in
On the other hand, in the gradation lighting control method of the display apparatus 100 according to the first embodiment, allocation of gradations to sub-frames is not evenly divided but to reduce the number of sub-frames in which the weighted element at the end of timeline in the weighting alignment is turned ON. That is, providing a period to turn OFF the light emitting element at the end of each sub-frame may allow charging of pseudo lighting element between the drive line and GND reduce the pseudo lighting in the period, and thus a reduction in the pseudo lighting can be expected.
It is preferable that the light emitting element corresponding to the weighted element at the end of weighting alignment is OFF in at least a half number of sub-frames in a single frame. Further, it is preferable that the longer the period of turning OFF the light emitting element corresponding to the weighted element at the end of weighting alignment, the greater effect in reducing pseudo lighting.
Further, as described above, uneven allocation of gradations among the sub-frames is allowed. Different allocation of gradation values between adjacent sub-frames allows to reduce the pseudo lighting. For example, among the sub-frames in a single frame, a difference in the gradation values between adjacent subs-frames can be set 10% or greater with respect to an average gradation value allocated to the sub-frames.
In the example of the first embodiment shown in
In the example described above, gradation values are non-uniformly allocated to the sub-frames with a ±5 increase/decrease of gradation value with respect to those allocated to the sub-frames in Comparative Example, in other words, with a difference in the gradation values set to 11. The increase/decrease of gradation value allocated to the sub-frames can be set with an appropriate value as well as 5 as shown above.
A second embodiment is configured such that, in comparison to Comparative Example in which gradation values are substantially uniformly allocated in each of the sub-frames, when a maximum gradation value that each sub-frame can express in 2Y−1, gradation values of ±2Y−2 are non-uniformly allocated in each of the sub-frames, as an example shown in
Timing Chart
Next, execution of gradation lighting control in the display device according to the second embodiment will be described with reference to the timing chart shown in
The 5 levels of weightings are indicated as weighted elements 0 to 4, as such the period of the weighted element 0 is t, the period of the weighted element 1 is 2t, the period of the weighted element 2 is 4t, the period of the weighted element 3 is 8t, and the period of the weighted element 4 is 16t. The LEDs to be lit with 12 gradation values are turned on at the weighted elements 2 and 3, and is turned off at the weighted elements 0, 1, and 4. The LEDs to be lit with 29 gradation values is turned on at the weighted elements 0, 2, and 4, and is turned off at the weighted element 1. The LEDs to be lit with the gradation value 0 is turned off at all the weighted elements 0 to 4.
In the sub-frame 1 of the frame 1, during the scanning period of COM1, SW11 is ON and SW12 and SW13 are OFF. During the scanning period of COM1, SW21 are turned ON at the weighted elements 2 and 3, turned OFF at the weighted elements 0, 1, and 4, and SW22 and SW23 are turned OFF at all the weighted elements 0 to 4, thus LED1 is turned ON with 12 gradations and LED2 and LED3 are turned OFF with 0 gradation value.
Similarly, during the scanning period of COM2, SW12 is ON and SW11 and SW13 are OFF. During the scanning period of COM1, SW22 are turned ON at the weighted elements 2 and 3, turned OFF at the weighted elements 0, 1, and 4, and SW22 and SW23 are turned OFF at all the weighted elements 0 to 4, thus LED1 is turned ON with 12 gradation value and LED2 and LED3 are turned OFF with 0 gradation value.
Similarly, during the scanning period of COM3, SW13 is ON and SW11 and SW12 are OFF. During the scanning period of COM1, SW23 are turned ON at the weighted elements 2 and 3, turned OFF at the weighted elements 0, 1, and 4, and SW22 and SW23 are turned OFF at all the weighted elements 0 to 4, thus LED1 is turned ON with 12 gradation value and LED2 and LED3 are turned OFF with 0 gradation value.
In the sub-frame 1 of the frame 2, during the scanning period of COM1, SW11 is ON and SW12 and SW13 are OFF. During the scanning period of COM4, SW21 are turned ON at the weighted elements 0 and 2, turned OFF at the weighted elements 0, 1, and 4, and SW22 and SW23 are turned OFF at all the weighted elements 0 to 4, thus LED1 is turned ON with 29 gradation value and LED2 and LED3 are turned OFF with 0 gradation value.
Similarly, during the scanning period of COM2, SW12 is ON and SW11 and SW13 are OFF. During the scanning period of COM4, SW22 are turned ON at the weighted elements 0 and 2, turned OFF at the weighted elements 0, 1, and 4, and SW22 and SW23 are turned OFF at all the weighted elements 0 to 4, thus LED1 is turned ON with 29 gradation value and LED 2 and LED3 are turned OFF with 0 gradation value.
Similarly, during the scanning period of COM3, SW13 is ON and SW11 and SW12 are OFF. During the scanning period of COM4, SW23 are turned ON at the weighted elements 0 and 2, turned OFF at the weighted elements 0, 1, and 4, and SW22 and SW23 are turned OFF at all the weighted elements 0 to 4, thus LED1 is turned ON with 29 gradation value and LED2 and LED3 are turned OFF with 0 gradation value.
The lighting control of the sub-frame 3 is similar to that of the sub-frame 1 and the sub-frame 4 is similar to that of the sub-frame 2, so that repetitive description will be appropriately omitted. As described above, in a single frame having four sub-frames, lighting with 82 gradation value can be executed in each pixel of LEDs 1, 5, and 9.
The gradation allocations to the sub-frames as described above is preferably predetermined for each gradation values corresponding to the number of the sub-frames or the like. For example, corresponding relations between the indicated gradation values and respective corresponding gradation values allocated to the sub-frames 1 to 4 are held as data to create a look-up table or the like and stored in the setting storage 54 shown in the functional block diagram in
In the examples illustrated above, when two gradation numbers are allocated to the sub-frames, the gradations of odd-numbered sub-frames are smaller than the gradation of even-numbered sub-frames, but the gradations of odd-numbered sub-frames may be greater than the gradation of even-numbered sub-frames.
Next, a display apparatus according to Example 1 will be described below.
In the display apparatus according to Example 1, 1728 LEDs (including three colors of light emitting elements; Red, Green, and Blue) were arranged in rows and columns at intervals of 4 mm. Further, 24 common lines connected to anodes of the LEDs were disposed in the lateral direction, while 216 lines (72 lines×3 colors) of drive lines connected to cathodes of the LEDs were disposed in the longitudinal direction.
A DC 5V constant voltage source was employed as the power supply. A FPGA was employed as the lighting controller 50 that time-divisionally applies voltage to the common lines. A P-channel FET was employed as the source driver, and an NPN transistor driven by a constant-current set to about 18 mA was employed as the sink driver. For the lighting controller 50 that turns ON and OFF the switches and changes sequence in the weighting alignments, a field programmable gate array (FPGA), a microcomputer, or a combination of those can be employed.
The display apparatus according to Example 1 was dynamically driven at a duty ratio of 1/24. The period of applying voltage to a single common line was 47.9 μs, and the period when no voltage is applied to any common lines was 10 μs. At this time, the sub-frame cycle is (47.9 μs+10 μs)×24 rows=1.39 ms.
Thus, 32 sub-frames were set at a cycle of 16.7 ms (60 Hz) that is common for video signals. A single sub-frame was subjected to a 6 levels weighted control by powers of two, and at t=729.2 ns, a sequence of t—>>2t—>>4t—>>8t—>>16t—>>32t was employed. With the use of 32 sub-frames and the 6 levels weighted control, a total of 2048 gradation value (26×32=2048) can be expressed.
In order to facilitate study of the effects, 1728 LEDs are arranged in a matrix of 24 rows×72 columns, and from upper left to lower right in the matrix, each unit of LEDs of 24 rows×24 columns were turned on to exhibit a diagonal lighting with 1024 gradation value, and the background, which was expressed by the other LEDs that were turned off with 0 gradation value.
The lighting was expressed by sub-frame modulation, in which among the sub-frames 1 to 32, the odd-numbered sub-frames were set with 48 gradation value in the diagonal line and 0 gradation value in the background, and the even-numbered sub-frames were set with 16 gradation value in the diagonal line and 0 gradation value in the background.
Visual inspection in a darkroom indicated that pseudo lighting was reduced in the display apparatus described above that in the display apparatus of Comparative Example 1 to be described below. Accordingly, the display apparatus according to Example 1 can be evaluated as a display apparatus with high display quality.
Next, a display apparatus according to Comparative Example 1 will be discussed. A display apparatus according to Comparative Example 1 has basically the same configuration as the display apparatus according to Example 1, but in a sub-frame modulation of the sub-frames 1 to 32, all the sub-frames were set with 32 gradations in the diagonal line and 0 gradation value in the background.
Visual inspection in a darkroom indicated that pseudo lighting was more significant in the display apparatus of Comparative Example 1 than that in the display apparatus of Example 1. Accordingly, the display apparatus according to Comparative Example 1 can be evaluated as a display apparatus with poor display quality.
Certain embodiments have been described above, but the scope of the invention is not limited to the above description, and should be widely understood based on the scope of claim for patent.
The display device according to the present invention can be utilized, for example, in a large screen television as well as a message board displaying information such as traffic updates.
Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
---|---|---|---|
2016-247763 | Dec 2016 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
20040239696 | Okabe et al. | Dec 2004 | A1 |
20160365033 | Song | Dec 2016 | A1 |
Number | Date | Country |
---|---|---|
2005-010741 | Jan 2005 | JP |
Number | Date | Country | |
---|---|---|---|
20180174502 A1 | Jun 2018 | US |