JP3241024B2 - Display device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image gradation display technique.

[0002]

2. Description of the Related Art Conventionally, as a technique for displaying an image with gradation by controlling a display time of a display element, for example, (1)
Kaji et al .: IEICE Technical Report on Image Engineering, Document No. I
T72-45 (1973-03) (1973.3.3.1)
2) There is a technology for a memory-type plasma display described in “Display of halftone moving images by AC-type plasma display”. This is achieved by allocating a certain light emission time (for example, one field of a television signal) to a plurality of subfields weighted by binary codes as a display period width, and controlling whether or not each subfield operates. , To control the gradation of the image. In addition, as a television-related technology for displaying gradation by time division,
(2) Murakami et al .: Journal of the Institute of Television Engineers of Japan, vol. 38, N
o. 9 (1984) "Color TV display using an 8-type pulse memory type discharge panel" and (3) Kogami et al .: Television Society Technical Report vol. 13, No. 58 (198
9) Reactive power recovery of a Townsend light emitting gas discharge television is described.

In the former case ((1)), as shown in FIG. 11, one field is divided into eight subfields b0 to b7, and each subfield is scanned and displayed in this subfield. .

In the latter case ((2) and (3)), as shown in FIG. 12, one field is divided into eight time regions (b0 to b7) each having a length corresponding to each subfield of a binary code (display period). ), The scanning is performed with a shift of 1H (horizontal scanning period) for each line, and a scanning pulse for a line address is slightly applied in each subfield so that the selection of the line of each subfield does not become two lines at the same time. It has been shifted.

[0005]

In the above prior art, the image quality deterioration of the gradation display such as flicker may not be visually recognized depending on the device specification, but when the display screen becomes large or the luminance becomes low. When the height of the moving image becomes high or when the moving image has a moving image, the disturbance of the gradation such as flicker is recognized. In the display technique of FIG. 11, the display screen is dark because the light emission time between one field is short. Therefore, no disturbance in the gradation is recognized. Further, in the display technique of FIG. 12, since the number of scanning lines is small, details of an image cannot be visually recognized. Therefore, also in this case, no disturbance in the gradation is recognized. However, for example, in a 40-inch class large gas discharge television having a higher luminance and a larger screen size than these cases, the maximum luminance of the image is set to 50 fL (# 171
cd / m ² ) or more, and when an image is displayed by the same method as in the above-described conventional technique, significant gradation disturbance occurs in a moving image. For example, in displaying a person's face, when the face moves, a phenomenon occurs in which a white streak runs on the cheek. In other words, in a smooth gradation display, when a display image moves (a so-called moving image), a streak is generated in the screen, and it is as if a certain gradation subfield is missing. This is a phenomenon that cannot be seen in a conventional cathode ray tube or the like.

[0006] Such disturbance of gradation in moving images is caused by instantaneous flicker of a specific pattern in time-division gradation display. This will be described below using the conventional gradation display technique of FIG.

FIG. 12 shows an example of a gray scale display of 256 gray scales (8-bit gray scale). For example, at the 127 gradation level, subfields b0 to b6 are activated, that is, the first half of one field emits light, and at the 128 gradation level at which the gradation of the next field is increased by one level, b7 is activated, that is, the second half of the field is activated. Moreover, part of the light is emitted.
That is, the operating position of the operating subfield changes greatly from the first half to a part of the second half in the field just by increasing the gradation by one level. The instantaneous light emission cycle at this time is from the light emission start time of the subfield b0 in the preceding field to the light emission start time of the subfield b7 in the succeeding field, and the time interval is 25 ms. This cycle 25m
The s causes flicker and causes the gradation to be disturbed. When the image is a moving image, the gradation is disturbed one after another in a cell of the screen, and appears as a streak that can be visually recognized clearly.

Next, the principle of the time-division gradation technology including the flicker will be described. As a human visual characteristic, luminance L
It is known that the brightness sensation L when an image is displayed by alternately repeating 1 for t1 seconds and luminance L2 for t2 seconds is represented by L = (t1L1 + t2L2) / (t1 + t2) (Talbot- Plateau's Law (Television Handbook, Volume 1, Section 3.4, 55
page)). However, this rule is satisfied when flicker is not felt (called fusion time).

FIG. 13 shows a critical fusion cycle of visual characteristics when a luminance is changed by changing a white display light emission time width using a memory type gas discharge television, that is, turning on and off a light emitting element at a constant luminance. The measurement result of a cycle in which flicker cannot be identified when lighting is repeated at a constant cycle is shown. In the figure, the upper broken line indicates the last subfield (b) of the next field from the start of the display period of the first subfield (b7) in the field by the gradation display technique of FIG.
0) shows a time interval until the start of the display period (FIG. 11).
In this example, one field is equally divided into eight subfields). The broken line in the lower part of FIG. 13 indicates the display period of the last subfield (b7) in the next field from the start of the display period of the first subfield (b0) in the field by the gray scale display technique shown in FIG. 12 shows a time interval up to the start point (in the example of FIG. 12, the display period of each 8-bit subfield in one field is 1: 2: 4
..: Weighted to a ratio of 128). As can be seen from FIG. 13, in the conventional gray scale display techniques of FIGS. 11 and 12, the luminance is several fL or more, and the last subfield of the next field is started from the start of the display period of the first subfield in a certain field. The interval until the start of the display period exceeds the critical fusion cycle. Therefore, when the light emission of each subfield changes as in the case of a moving image, instantaneous flicker is felt particularly on a bright screen, and gradation is disturbed. Usually, the average luminance required for the display device is 50 f
Therefore, the critical fusion period of the visual characteristics is 20 or more.
ms or less, but if the value is in the vicinity of this value, even if this value is exceeded, the disturbance of the gradation is improved.

Further, in the above-mentioned prior art, the utilization rate of the time within one field as the light emission time is poor, that is, since the light emission time is short, the brightness of the screen is reduced.

SUMMARY OF THE INVENTION An object of the present invention is to improve the drawbacks of the prior art, to provide a technique capable of suppressing disturbance of gradation even for a moving image or a high-luminance image and increasing the light emission utilization rate within one field. Is to do.

[0012]

According to the present invention, there is provided a display apparatus for displaying a gradation image using a plurality of subfields weighted by the number of display pulses. , The weight is higher, and the number of display pulses is
A plurality of new subfields in one field,
At least two of the upper subfields that are approximately equal
Multiple lower subfields between upper subfields
And a plurality of the upper sub-fields which are substantially equal to each other.
Subfields that operate in the same
Other subfields, except for the field
Field of the other subfield in the preceding field.
The start of the display period of the first subfield and the following
The last sub-field of the other sub-field in the field.
Of the visual characteristics
Arrange subfields to be less than the critical fusion period
You.

(2) In a display device for displaying an image having a gradation by using a plurality of subfields weighted by the number of display pulses, the weighting is performed on the upper side, and
Subfields with approximately the same number of fields
Of the upper sub-fields having a plurality of
Multiple lower fields between at least two upper subfields
And a plurality of substantially equal sub-fields.
The same operating state is linked in the upper subfield
Other subfields except for
Is an adjacent field and the other sub
Open the display period of the first subfield of the field.
The start time and the other subfields in the subsequent field
Interval from the beginning of the display period of the last subfield
Subfields are set to be less than or equal to 20.8 ms
You.

[0014]

[0015]

[0016]

[0017]

[0018]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a principle explanatory diagram for explaining the basics of the present invention. In this case, the number of scanning electrodes is 240, and the signal to be displayed is 8 bits (8 subfields b0, b1,
b2, b3, b4, b5, b6, b7), each bit is encoded by a binary code, and 256 gray scales can be displayed.

In the figure, the vertical axis is the horizontal scanning electrode 2.
Forty rows (the upper half of the display panel), the horizontal axis shows the time for two fields (1/30 second). In this explanatory diagram, the subfields are arranged in one direction without allocating the entire time range of one field as a subfield. With such a configuration, the light emission start time (display period start time) of the first subfield b0 in the field and the last subfield b7 in the next field
(Tm) between the start of light emission (start of display period)
Is shorter than the critical fusion period of the visual characteristics (about 20 ms). The arrangement order of each subfield does not need to be limited to the illustrated order. Also, the light emission time may be packed in the field on the right or left side of the field. In FIG. 1, the order of the subfields is reversed,
When the order is from b7 to b0 in the field, the time interval from the light emission start time of b7 (display time start time) to the light emission start time of b6 of the next field (display time start time) is: It is shorter than the critical fusion cycle (about 20 msec).

FIG. 2 is a diagram showing an example of a circuit configuration in a gas discharge television device as a display device according to the present invention.
The video signals G, B, and R separated into green (G), blue (B), and red (R) color signals of the television signal are A / D converters 1-1, 1-2, and 1-3, respectively. From the analog signal
Bit (8 subfields b0, b1, b2, b3, b
4, b5, b6, b7) digital signal (binary code)
And stored in the frame memory (or field memory) 2. On the other hand, reading out of the frame memory 2 is performed by using a dedicated read-out ROM 5 so as to make a timing suitable for the gradation sub-field. The read ROM 5 is operated by the counter 4 that counts the clock signal CLK. The reset of the counter 4 is performed using a V (vertical synchronization) signal of the television signal or an H (horizontal synchronization) signal as necessary. Frame memory 2
Are read from each subfield (b0, b2,...) Of FIG.
This is performed by accessing the address where the subfield signal of each scanning electrode is stored at the timing of b7). Each subfield signal read from the frame memory 2 is applied to shift registers 8 and 11 of a driver circuit for an auxiliary anode of the light emitting element, and further passed through drivers 9 and 10 to output signals of the light emitting element constituting the gas discharge panel 3. Are applied to the auxiliary anodes S1, S2, S3,..., S1 ', S2', S3 ',.

On the other hand, the ROM 6 for the cathode and the ROM 7 for the anode
Respectively use the output of the counter 4 to convert the arrangement signals of the subfields into the shift registers 13, 14 and 17, 18.
Add to Further, shift registers 13, 14, and 1
The signals from 7 and 18 are applied to drivers 15, 16 and 19 and 20, respectively, where the driving signals for the anode and cathode of the light emitting element of the gas discharge panel 3 are generated. The anode of the light emitting element has anode lead wires A1, A2, A3.
A480 are provided, and the cathode is provided with cathode leads K1, K2, K3... K240, K241. These ROM, shift register and driver constitute a drive circuit for selecting a light emitting element to be displayed. Note that, in the case of this configuration example, the gas discharge panel 3 is vertically divided into two parts, so that two scanning electrodes can be driven simultaneously.

FIG. 3 is a partially enlarged view of the gas discharge panel 3 and shows the electrode wiring of the light emitting element. The gas discharge panel 3
A plurality of light emitting elements 30 are arranged in a matrix of rows and columns. The light emitting element 30 has three electrodes of a cathode, an anode, and an auxiliary anode, and has a memory function. Each light emitting element 3
A first electrode lead 32 (k1, k2,... Kl) and a third electrode lead 31 (A1, A2,... Al) are provided on the cathode and the anode, respectively, in the lateral direction. Are provided with auxiliary electrode lead wires 33 (S1, S2,...) In the vertical direction. As described above, when the gas discharge panel 3 is set to the number of horizontal scanning electrodes 1 = 480 and the panel is vertically divided into two and driven simultaneously by two rows, the auxiliary electrode lead wires 33 are separated at the center of the panel. The first electrode lead 32 (k
, K1), the third electrode lead wire 31 (A1, A2,
.. Al) and the auxiliary electrode lead wires 33 (S1, S2,...) Are respectively provided with the cathode driver 19 (or 20) of FIG.
Drive signals from the anode driver 15 (or 16) and the auxiliary anode driver 9 (or 10) are added.

FIG. 4 is a diagram showing a cross section of the light emitting element 30. A first electrode (cathode) 22 is made of Ba, Ni,
It is formed of a material such as LaBa. On the other hand, a third electrode (display anode) 24 is formed on the face plate 28 by a printing technique. Also, the discharge space (display discharge space 25 and auxiliary discharge space 27) shown in the figure is formed by stacking a number of perforated spacers, and the second electrode (auxiliary anode) shown in the figure is formed.
23 are arranged. When a discharge (display discharge) occurs between the first electrode 22 and the third electrode 24, ultraviolet rays are generated from a gas (Xe or a mixed gas of Ne-Xe, He-Xe, etc.) in the display discharge space 25, and fluorescence is generated. The light body 26 emits light to perform display. A so-called pilot discharge (auxiliary discharge) is generated between the first electrode 22 and the second electrode 23, and this auxiliary discharge is transferred to a display discharge between the first electrode 22 and the third electrode 24. This is controlled by the presence or absence of a pulse applied to the second electrode 24. Since this auxiliary discharge does not excite the phosphor 26, it does not affect display light emission.

Next, the discharge state between the electrodes will be described with reference to FIG. In FIG. 5, Vk indicates a voltage waveform applied to the first electrode lead line, and 40 indicates a pulse for addressing one line of the gas discharge panel 3, which is referred to as a first electrode scanning pulse. In the example of FIG. 5, the pulse width of the first electrode pulse is the same as the time width Δ assigned for addressing one line. For example, when the scanning time of each line is 1H, 240 lines are addressed in one field (the number of lines in the upper half of a panel driven simultaneously by two lines), and 8-bit gradation display is performed, Δ ≒ 8 μs. Vs indicates a pulse voltage waveform applied to the second electrode lead,
Reference numeral 1 denotes a second electrode pulse, which has a smaller pulse width than the first electrode scanning pulse 40 and is located behind the time width Δ. This second
The presence / absence of the electrode pulse 41 changes depending on the content of the television signal, that is, “1” and “0” of the subfield signal. VA indicates the waveform of the pulse voltage applied to the third electrode lead wire. For the same line number of the first electrode lead wire and the third electrode lead wire, the width of the voltage applied to the third electrode in FIG. Immediately after the first electrode scanning pulse 40, the narrow pulse 41 is continuously applied by the number of pulses corresponding to the number of gradation bits.

In a period III in the drawing, a pulse 42 having a narrow pulse width is first applied to the third electrode. Since a large number of charged particles are present in the display discharge space 25 due to the switching in the period II, the pulse 42 causes the first electrode and the third
A pulsating discharge occurs between the electrodes. This pulsed discharge further generates charged particles in the display discharge space 25,
The next pulse 43 also discharges. As described above, in the period III, the discharge continues while the pulse is continuously applied or until a new voltage that stops the discharge is applied to the first electrode. This function is called a pulse memory function. By this pulse discharge, the phosphor 26 of FIG. 4 is excited to perform display light emission.

When the display is not to be emitted, the pulse 41 of the second electrode shown in FIG. 5 is removed. In this case, switching is not performed, and no discharge occurs between the first electrode and the third electrode, so that the number of charged particles in the display discharge space 25 in FIG. 4 is small. Therefore, even if the pulses 42 and 43 are applied to the third electrode, no discharge occurs, and the phosphor 26 in FIG. 4 is not excited.

Therefore, the pulse 41 of the second electrode serves to control the discharge between the first electrode and the third electrode, and the display brightness is controlled by the presence or absence of this pulse.

FIG. 6 is an explanatory diagram for displaying an image on the gas discharge panel 3 in 256 gradations using an 8-bit binary code.
One field in FIG. 1 (about 1 in the case of an NTSC television signal)
/ 60 seconds = 16.7 msec). FIG. 3 shows the voltage waveform Vk applied to the first electrode and the third waveform.
3 shows a voltage waveform VA applied to an electrode. Eight scanning pulses 40 corresponding to each subfield are applied to the first electrode during one field. Pulse 42 applied to third electrode
Starts immediately after the application of the scanning pulse 40 and ends before the next scanning pulse 40 comes, as shown in FIG. The number of each of the pulses 42 is determined by the subfields b0, b1,.
It is proportional to the weight of the display period of b6 and b7, and the ratio is 1:
2: 4: 8...: 128, 2
56 gradations are realized. The control as to whether or not to discharge the pulse train of each third electrode is performed in subfields b0 and b0.
1,..., B6 and b7, depending on whether or not there is a pulse (41 in FIG. 5) of the second electrode corresponding to the scanning pulse. In addition,
In FIG. 5, when the light emission in the period II cannot be neglected, the number of pulses of the third electrode is distributed in consideration of the luminance due to the light emission. Here, the period from the start of the display period of subfield b0 to the end of the display period of b6 in FIG. 6 is 3.3 m.
When the absolute value of the number of pulses of the third electrode is determined so as to be on the order of seconds, the above-described critical fusion period is 20 (= 3.3 + 1).
6.7) msec, and disturbance of gradation for a moving image can be suppressed.

In the configuration shown in FIGS. 1 and 6, the start of the display period of the first subfield of the subfield array in a certain field and the start of the display period of the last subfield of the subfield array in the next field In order to make the time interval (Tm) shorter than the critical fusion period of the visual characteristics, the entire display period is considerably shortened. However, in order to increase the emission time, at least one of the subfields of the binary code configuration is used. The same effect can be obtained by dividing one subfield and operating the divided subfield in a time zone different from the subfield operation time zone in the case of FIGS.

FIGS. 7 and 8 are explanatory diagrams of an embodiment of the present invention.

In the embodiment shown in FIG. 7, the signal to be displayed is encoded by 8 bits (8 subfields b0, b1,..., B7), and the most significant subfield b7 is converted to the subfield b71.
And b72, and divide the emission time region of b71 and b72 by 1
It is assigned to the first and last positions of the field, and the emission order (operation order) of each subfield is b71, b0, b1,.
b2,... b5, b6, b72 (b71, b5,
... may be b1, b0, b72). In this case, b7
1, subfields b0, b1, b2, excluding b72,
.., B5 and b6, the first subfield of the field is b0, and the last subfield of the next field is b6. The interval between the light emission start time (display period start time) of these two subfields is 20.8 ms, which is almost the same as the critical fusion period, and an effect of improving the image quality of a moving image can be obtained. In the case of the present embodiment, in the display device having the same configuration as that shown in FIG. 2, nine sub-pixels are applied to the first electrode during one field (about 1/60 second in the case of the NTSC television signal). Fields b71, b0,
Scan pulses corresponding to b1,... b6, b72 are applied. The pulse 42 applied to the third electrode is a scan pulse 40
And ends before the next scan pulse 40 comes. For example, if b7 is equally divided into b71 and b72, the number of pulses in each of the subfields b71, b0,
The ratio is 64: 1: corresponding to b1,... b6, b72.
2: 4: 8...: 64: 64. In this case, b7
When (pulse ratio 128, b7 = b71 + b72) is turned on (operating state), two subfields b71 and b72 are turned on. The control as to whether or not to discharge the pulse train of each of the third electrodes depends on the sub-field b71,
The determination is made based on the presence or absence of the second electrode pulse (40 in FIG. 5) corresponding to the scan pulses b0, b1,... b6, b72. When the scanning time of each line is 1H, 240 lines (the number of lines in the upper half of the panel driven simultaneously by two lines) are addressed in one field, and nine control operations of b71, b0, b1,... B6, b72 are required. , Δ = 1H / 9 = 7.05 μs. When the vertical blanking period is used, Δ = 1 field / 240 × 9 = 7.72 μs.

In the embodiment shown in FIG. 8, a signal to be displayed is encoded by 8 bits (8 subfields b0, b1,... B7), and two subfields of subfields b6 and b7 are equally divided into b6 and b7. Is b61 and b62, b7 is b71 and b72, and b61 and b71 are arranged at the beginning of the subfield array in the field, b62 and b72 are arranged at the end, and the order in the field is b61, b71, b0, b
1, b2, b3, b4, b5, b62, b72. In this case, the first subfield in the field is b0, and the last subfield in the next field is b5. At this time, the interval between the light emission start time points (display period start time points) of the two subfields is 18.8 ms.
, Which is shorter than the critical fusion cycle (20 ms). In this example, the scanning pulse of the first electrode applied to one field is ten per line, and the pulse width Δ is 1H / 10
≒ 6.3 μs, but if the vertical retrace period is also used, Δ
≒ 6.9 μs.

FIG. 9 shows two of the field memories 91 and 92.
In order to further improve the image quality in the embodiment of FIG. 7, subfields b71, b72, b
6 is performed. Subfield b7
Is equally divided into two, b71 and b72, b6, b71,
All of b72 have the same display period (the number of pulses of the third electrode). At that time, b6 = 1, b7 = 0 (1; operation (O
N), 0; when not operating (OFF)), b71, b72,
One of the b6 may be set to the operating state (ON).
When 6 = 0 and b7 = 1, any two of b71, b72 and b6 may be set to the operating state (ON). At this time, which subfield is to be activated (ON) is determined in this example from the states of b6, b71, and b72 one field before. For example, in FIG. 9, when the second field is in a light emitting state, the previous field memory 91
According to the table of FIG. 10 through the arithmetic circuit 93 for comparing the signal of the field memory 92 with the subfield b
6, ON (1; operation) and OFF (0; non-operation) of b71 and b72 are determined.

FIG. 10A shows that the first field is b6 =
When 1, b7 = 0, the second field is b6 = 0, b7
B6, b71 and b72 when = 1. Here, A indicates the subfields b0 to b5, and the cross indicates that it does not depend on the value of A, that is, A may be any value. In addition, FIG.
This shows a case where the fields b6 = 0 and b7 = 1 and the second field changes to b6 = 1 and b7 = 0. As described above, for example, by controlling the subfields b6, b71, and b72 of the subsequent field between the adjacent fields according to the signal state of the previous field, the emission time can be dispersed, and the image quality of a moving image is improved. be able to. Note that b6, b71 when b6 = 1, b7 = 0, or b6 = 0, b7 = 1 from b6 = 0, b7 = 0,
The selection of the operation of b72 is determined from the state of A. The above is the case where the subfield b7 is divided equally, but the same applies to the case where two or more subfields are divided. FIG.
In this embodiment, only the subfield b7 is divided, and in the embodiment shown in FIG. 8, only b6 and b7 are divided. However, other subfields may be divided. The selection of the field to be divided and the arrangement of the display time regions are determined in consideration of the simplicity of the device configuration and the effect of improving the disturbance of gradation display.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited to the above embodiments. For example, the present invention includes a case where the direction of the time axis in the subfield arrangement of FIGS. 7 and 8 is reversed. In addition, as a display device according to the present invention, a gas discharge television device using a gas discharge light emitting element is representative, but the present invention is not limited to this.

[0037]

According to the present invention, the disturbance of the gradation can be improved without lowering the brightness of the image.

[Brief description of the drawings]

FIG. 1 is a principle explanatory diagram of the present invention.

FIG. 2 is a diagram showing an example of a circuit configuration for an embodiment of the present invention.

FIG. 3 is a diagram showing a configuration example of a gas discharge panel used in an embodiment of the present invention.

FIG. 4 is a sectional view of a light emitting device of a gas discharge panel used in an embodiment of the present invention.

FIG. 5 is a voltage waveform chart for explaining the operation of the light emitting device shown in FIG.

FIG. 6 is a principle explanatory diagram of the present invention.

FIG. 7 is a diagram showing one embodiment of the present invention.

FIG. 8 is a diagram showing one embodiment of the present invention.

FIG. 9 is a diagram illustrating an example of an arithmetic circuit used in an embodiment of the present invention.

FIG. 10 is a diagram illustrating the operation of the arithmetic circuit in FIG. 9;

FIG. 11 is a diagram showing a conventional example of a gradation display technique.

FIG. 12 is a diagram showing another conventional example of the gradation display technique.

FIG. 13 is a diagram showing a measurement result example of a critical fusion period.

[Explanation of symbols]

 1: A / D converter, 2: Frame memory, 3: Gas discharge panel, 4: Counter, 5, 6, 7, ROM, 8, 11, 13, 14, 17, 18: Shift register, 9, 10, 15, 16, 19, 20: driver, 21: substrate, 22: cathode, 23: auxiliary anode, 24: display anode, 25: display discharge space, 26: phosphor, 27: auxiliary discharge space, 28: face plate, Reference numeral 30 denotes a discharge cell (light emitting element), 31 denotes a third electrode lead, 32 denotes a first electrode lead, 33 denotes a second electrode lead, 91 and 92 denotes a field memory, and 93 denotes an arithmetic circuit.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Mutsumi Suzuki 1-280 Higashi Koigabo, Kokubunji-shi, Tokyo Inside the Central Research Laboratory, Hitachi, Ltd. (56) References JP-A-4-211294 (JP, A) 9-83911 (JP, A) JP-A-63-139485 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G09G 3/28 G09G 3/20 611 G09G 3/20 641 G09G 3/20 642

Claims (2)

(57) [Claims] 1. A display device for displaying an image with gradation using a plurality of subfields weighted by the number of display pulses, wherein a subfield having a higher weight and a substantially equal number of display pulses is used. A plurality of upper sub-fields having substantially the same number in one field
A plurality of lower sub-fields are arranged between the two upper sub-fields, and other sub-fields of the plurality of substantially equal upper sub-fields other than the sub-fields which are operated in the same manner in conjunction with each other are arranged. The display period of the first sub-field of the other sub-fields in the preceding field in the adjacent field and the display period of the last sub-field of the other sub-field in the subsequent field; A display device, wherein subfields are arranged so that the interval between the subfields is equal to or less than a critical fusion period of visual characteristics. 2. A display device for displaying an image with gradation using a plurality of subfields weighted by the number of display pulses, wherein a subfield having a higher weight and a substantially equal number of display pulses is used. A plurality of upper sub-fields having substantially the same number in one field
A plurality of lower sub-fields are arranged between the two upper sub-fields, and other sub-fields of the plurality of substantially equal upper sub-fields other than the sub-fields which are operated in the same manner in conjunction with each other are arranged. The display period of the first sub-field of the other sub-fields in the preceding field in the adjacent field and the display period of the last sub-field of the other sub-field in the subsequent field; Wherein the sub-fields are arranged so that the interval between them is 20.8 ms or less.