JP2003280579A - Drive method and driving device for matrix type display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress reduction over time in luminance of a matrix type display device even though the number of scanning lines is increased to thereby realize a luminance service life which is similar to the luminance service life of a display device having the less number of scanning lines. <P>SOLUTION: In an organic EL panel 11, light emitting elements are formed at the crossing points of a plurality of anode lines and a plurality of cathode lines both of which are arranged in a matrix manner. A control circuit 13 periodically scans scanning lines (the cathode lines) through a row driver 12a and provides current signals to desired signal lines (the anode lines) from a column driver 12b to cause the light emitting elements formed at the crossing points of these lines to emit light. When there exist scanning lines on which light emitting elements, that are driving objects, do not exist in one scanning period, the circuit 13 inhibits the scanning operation for the scanning lines on which the light emitting elements do not exist. Thus, the circuit 13 controls so that the number of scanning lines per scanning period is reduced and the scanning interval for the scanning lines, on which driving object light emitting elements exist, is extended. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving method and a driving apparatus of a matrix type display device having a plurality of light emitting elements formed at respective intersections of a predetermined number of anode lines and cathode lines.

[0002]

2. Description of the Related Art FIG. 6 shows a conventional driving method of an organic EL display device. This driving method is called a simple matrix driving method, and here, the anode lines A1 to AN and the cathode lines B1 to BM are arranged in a matrix.
Organic EL having a light-emitting element (pixel) formed at the intersection with
An example in which a display device is driven is shown. In this case, one of the anode lines A1 to AN and the cathode lines B1 to BM (cathode lines B1 to BM in the example of FIG. 6) is sequentially selected and scanned at fixed time intervals, and the other is synchronized with this scanning cycle. (Anode lines A1 to AN in the example of FIG. 6) are driven by the outputs from the current sources 1-1 to 1-N, which are drive sources, so that the light emitting element at a desired intersection position emits light. .

Scanning switches 2-1 to 2-1 to the cathode lines B1 to BM for selecting a power supply voltage (+ Vcc) or a ground potential (0V) which is a reference potential for performing sequential scanning.
2-M is connected. These scan switches 2-1 to 2
-M is scanned while switching from the power supply terminal side to the ground terminal side in sequence at a fixed cycle, so that cathode lines B1 to B
Ground potential (0V) is applied to M sequentially. on the other hand,
Drive switches 3-1 to 3-N for selecting the current sources 1-1 to 1-N or the ground potential (0V) supplied from the power supply terminals are connected to the anode lines A1 to AN. By selectively ON / OFF controlling these drive switches 3-1 to 3-N in synchronization with the scanning cycle of the scan switches 2-1 to 2-M, the anode lines A1 to A1- A
Connect N to current sources 1-1 to 1-N. As a result, the drive current is supplied to the light emitting element at the desired intersection position.

For example, when the light emitting elements E1,1 and E1,2 are caused to emit light, as shown in FIG. 6, only the scan switch 2-1 is switched to the ground terminal side so that the cathode line B1 becomes the ground potential. While scanning, drive switches 3-1 and 3-2
To the current source side to switch the anode wires A2 and A3 to the current source 1-
Connect to 1, 1-2 respectively. Then, as indicated by arrows in the figure, the drive current is supplied only to the light emitting elements E1,1 and E1,2 to emit light. By repeating such scanning and driving operations at high speed, it is possible for the human eye to recognize that the light emitting elements E1,1 and E1,2 are emitting light at the same time due to the afterimage phenomenon. In addition, the non-selected cathode line B
2 to BM have a reverse bias voltage (+ Vc) of the same potential as the power supply voltage.
By applying c), erroneous light emission of the light emitting elements corresponding to the cathode lines B2 to BM is prevented. Then, by selectively performing such scanning and drive control on the scan switches 2-1 to 2-N and the drive switches 3-1 to 3-M, the light emitting element at an arbitrary position is similarly made to emit light. You can

[0005]

In the conventional driving method described above, the cathode lines B1 to BM, which are scanning lines, are scanned at a duty ratio of 1 / M for each scanning cycle. Therefore,
Display luminance Ld [cd / required for organic EL display device
In order to obtain m ² ], each light emitting element must emit light with a high luminance of Ld × M [cd / m ² ] when the corresponding cathode ray is scanned. Therefore, the display brightness Ld
Even when is constant, if the number of scanning lines M increases, that is,
As the drive duty ratio 1 / M becomes smaller, it becomes necessary to further increase the light emission luminance (= Ld × M [cd / m ² ]) of each light emitting element during scanning, so that the drive current flowing through them also becomes proportional. Will increase. However, the life of the EL display device has a characteristic that it is affected by the magnitude of the drive current flowing through each light emitting element. As a result, the relationship between the number of scanning lines and the 50% life reduction of the light emitting element (time until the emission luminance is reduced to 50% of the initial value) is determined under predetermined conditions (the sample is a green light emitting element, the initial luminance = 400). [Cd / m ² ], 85 ° C
As shown in FIG. 7 which shows the actual measurement result in (operation), when it is intended to realize a constant display luminance Ld [cd / m ² ] in the organic EL display device, the number of scanning lines M increases and the drive duty ratio 1 The smaller the value of / M, the more significant the deterioration of the luminance with time. That is, a display device having a large number of scanning lines, such as a large-sized or high-resolution display, has a problem that the brightness life is shortened.

The present invention has been made in view of the above circumstances, and suppresses deterioration of luminance with time even when the number of scanning lines of a matrix type display device is large, and has a luminance equivalent to that of a display device having a small number of scanning lines. An object of the present invention is to provide a driving method and a driving device of a matrix type display device that can realize a life.

[0007]

In the method of driving a matrix type display device according to claim 1, one of a plurality of anode lines and one of a plurality of cathode lines is a scanning line and the other is a signal line. By periodically scanning the scanning line group and applying a current signal to a desired signal line, the light emitting element formed at the intersection of the scanning line and the signal line is caused to emit light. In this case, when there is a scanning line in which the light emitting element to be driven does not exist in one scanning cycle of the scanning line group, scanning for one scanning cycle is prohibited by prohibiting the scanning of the scanning line in which the light emitting element does not exist. Control is performed to reduce the number of lines and extend the scanning period for the scanning line in which the light emitting element to be driven exists. Therefore, since the driving duty ratio of the scanning line scanned in such a control state becomes large, when the emission brightness of the light emitting element that emits light in accordance with the scanning of the scanning line is reduced, that is, the signal Even when the level of the current signal (driving current of the light emitting element) applied to the line is reduced, it is possible to obtain the display brightness required in the matrix display device. As a result of reducing the driving current of the light emitting element,
Even when the number of scanning lines of the matrix type display device increases, it is possible to suppress the deterioration of the luminance with time, and to realize a luminance life equivalent to that of a display device having a small number of scanning lines.

Also in the method of driving the matrix type display device according to the second aspect, one of the plurality of anode lines and one of the plurality of cathode lines is a scanning line and the other is a signal line. In addition, while periodically scanning the scanning line group, by applying a level-adjustable current signal to a desired signal line, the light emitting element formed at the intersection of the scanning line and the signal line is adjusted according to the current signal level. Light is emitted at multiple gradation levels. In this case, the scanning period of each scanning line in one scanning cycle of the scanning line group is controlled so as to be a period proportional to the maximum gradation level of the driven light emitting element existing on the scanning line. Therefore, for example, when the light emitting element to be driven does not exist on the scanning line, the maximum gradation level of the light emitting element to be driven is regarded as zero, and scanning is performed on the scanning line where the light emitting element does not exist. Absent. Also,
The scanning line including the light emitting element to be driven is controlled so that the scanning period is shortened when the maximum gradation level of the light emitting element to be driven is relatively low, and thus such a scanning line exists. In the case where there is a scanning line in which the above-mentioned scanning is not performed, the scanning period of the other scanning lines, that is, the scanning line in which the drive target light emitting element in which the maximum gradation level is relatively high exists. Will be postponed. Therefore, since the driving duty ratio of the scanning line in which the light emitting element is required to be displayed at a relatively high gradation level is large, the light emission luminance of the light emitting element which emits light in response to the scanning of the scanning line. Is reduced,
In other words, even when the level of the current signal (driving current of the light emitting element) given to the signal line is reduced, it is possible to obtain the display brightness required in the matrix display device. In addition, for a scanning line in which a light emitting element that performs display at a relatively low gradation level is present, the drive duty ratio is small, but the level of the current signal given to the signal line during scanning is inherently small. I'm done. As a result, even when the number of scanning lines of the matrix type display device is increased, it is possible to suppress the deterioration of the luminance over time, and to realize a luminance life equivalent to that of a display device having a small number of scanning lines.

In a method of driving a matrix type display device according to a third aspect, one of a plurality of anode lines and one of a plurality of cathode lines is a scanning line, and the other is a signal line, and a scanning line group. By periodically applying a current signal to a desired signal line while scanning, the light emitting elements formed at the intersections of the scanning line and the signal line are caused to emit light. In this case, the display mode of the matrix type display device is a normal display mode in which all the scanning lines are scanned to display the entire screen, and a partial display in which only a specific scanning line group is scanned to perform display using only a predetermined range. Mode is set, and thereby the scanning period of the scanning line scanned in the partial display mode is extended. Therefore, in the partial display mode, the driving duty ratio of the scanning line to be scanned becomes large. Therefore, when the emission brightness of the light emitting element that emits light in response to the scanning of the scanning line is reduced, that is, in the signal line. Even when the level of the applied current signal (driving current of the light emitting element) is reduced, it is possible to obtain the display brightness required in the matrix display device. Therefore, during the period in which the matrix type display device is driven in the partial display mode, the driving current of the light emitting element is reduced, so that the deterioration of the luminance with time is suppressed. It becomes more prominent as the driving period in (3) becomes longer. As a result, even when the number of scanning lines of the matrix type display device is increased, it is possible to suppress the deterioration of luminance with time as a whole, and it is possible to realize the same luminance life as that of a display device with a small number of scanning lines. It will be.

When the driving method according to the third aspect is adopted, the display brightness in the normal display mode is relatively lowered like the driving method for the matrix type display device according to the fourth aspect, and It is possible to perform control to relatively increase the display brightness in the partial display mode. According to this driving method, in the partial display mode in which the display luminance is relatively high, the driving duty ratio of the scanning line to be scanned is increased for obtaining the required luminance for the same reason as in claim 3. The level of the required drive signal can be reduced. Also,
Even in the normal display mode in which full-screen display is performed, the display brightness is relatively low, so that the level of the drive current applied to the light emitting element during the scanning line scanning can be suppressed. That is, in any of the normal display mode and the partial display mode, the driving current of the light emitting element is reduced, so that the deterioration of luminance with time is suppressed. Therefore, it is useful in extending the luminance life.

Further, when the driving method according to claim 4 is adopted, as in the driving method for the matrix type display device according to claim 5, the light emission luminance of the light emitting element at the time of scanning the scanning line is set to the luminance at the normal display mode. By setting the display brightness in the normal display mode to be relatively low and the display brightness in the partial display mode to be relatively high by setting the same in both the partial display mode and Thus, it is possible to improve the brightness life.

When the driving method according to the third aspect is adopted, as in the driving method for the matrix type display device according to the sixth aspect, the light emission luminance of the light emitting element during the scanning line scanning in the normal display mode is relatively changed. May be set to a relatively high value, and the emission brightness of the light emitting element during scanning line scanning in the partial display mode may be set to a relatively low value. With such a setting, the level of the drive current applied to the light emitting element at the time of scanning line scanning can be suppressed in the partial display mode, which is advantageous in extending the luminance life as a whole. Become.

When the driving method according to claim 6 is adopted, as in the driving method for the matrix type display device according to claim 7, the light emission luminance of the light emitting element during the scanning line scanning in the normal display mode is relatively changed. The display brightness in the normal display mode and the partial display mode are set to the same level by setting the display brightness in the partial display mode to a relatively low value while setting the emission brightness of the light emitting element in the partial display mode to be relatively low. However, this also makes it possible to improve the brightness life as a whole.

According to the driving device of the matrix type display device described in claim 8, the control circuit periodically scans the scanning line group and applies a current signal to a desired signal line to thereby scan the scanning line group and the scanning line group. The light emitting element formed at the intersection of the signal lines is controlled to emit light. In this case, if there is a scan line in which the light emitting element to be driven does not exist in one scan cycle of the scan line group, the control circuit prohibits the scan of the scan line in which the light emitting element does not exist, thereby performing one scan. Control is performed to reduce the number of scanning lines per cycle and to extend the scanning period for the scanning line in which the light emitting element to be driven exists. Therefore, since the driving duty ratio of the scanning line scanned in such a control state becomes large, when the emission brightness of the light emitting element that emits light in accordance with the scanning of the scanning line is reduced, that is, the signal Even when the level of the current signal (driving current of the light emitting element) applied to the line is reduced, it is possible to obtain the display brightness required in the matrix display device. As a result of reducing the drive current of the light-emitting element in this way, even when the number of scanning lines of the matrix type display device is increased, the deterioration of the luminance with time is suppressed, and a luminance life equivalent to that of a display device with a small number of scanning lines is realized. It will be possible.

According to another aspect of the present invention, in the drive device for the matrix type display device, the control circuit cyclically scans the scanning lines and gives a level-adjustable current signal to the desired signal lines, thereby controlling the scanning lines. The light emitting elements formed at the intersections of the scanning lines and the signal lines are caused to emit light at a plurality of gradation levels according to the current signal level. In this case, the control circuit controls the scanning period of each scanning line in one scanning cycle of the scanning line group to be a period proportional to the maximum gradation level of the light emitting element to be driven existing on the scanning line. Therefore, for example, when the light emitting element to be driven does not exist on the scanning line, the maximum gradation level of the light emitting element to be driven is regarded as zero, and scanning is performed on the scanning line where the light emitting element does not exist. Absent.

Further, the scanning line in which the light emitting element to be driven is present is controlled so that the scanning period is shortened when the maximum gradation level of the light emitting element to be driven is relatively low. When there is a scan line or when there is a scan line in which the above scanning is not performed, a scan line other than that, that is, a scan in which there is a drive target light emitting element in which the maximum gradation level is relatively high The line scan period will be lengthened. Therefore, for a scanning line including a light emitting element that is required to be displayed at a relatively high gradation level, the drive duty ratio becomes large,
Even when the emission brightness of the light emitting element that emits light in response to scanning of the scan line is reduced, in other words, the level of the current signal (driving current of the light emitting element) applied to the signal line is reduced, matrix display It is possible to obtain the required display brightness in the device. In addition, for a scanning line in which a light emitting element that performs display at a relatively low gradation level is present, the drive duty ratio is small, but the level of the current signal given to the signal line during scanning is inherently small. I'm done. As a result, even when the number of scanning lines of the matrix type display device is increased, it is possible to suppress the deterioration of the luminance over time, and to realize a luminance life equivalent to that of a display device having a small number of scanning lines.

According to the driving device of the matrix type display device of the tenth aspect, the control circuit gives a current signal to a desired signal line while periodically scanning the scanning line group, thereby supplying the scanning line and the scanning line group. The light emitting element formed at the intersection of the signal lines is controlled to emit light. In this case, the control circuit
As the display mode of the matrix type display device, there are a normal display mode in which all scanning lines are scanned to display the entire screen, and a partial display mode in which only a specific scanning line group is scanned to perform display using only a predetermined range. By setting, control is performed to extend the scanning period of the scanning line scanned in the partial display mode. Therefore, in the partial display mode, the drive duty ratio of the scanning line to be scanned becomes large,
Even when the emission brightness of the light emitting element that emits light in response to scanning of the scan line is reduced, that is, the level of the current signal (driving current of the light emitting element) applied to the signal line is reduced, the matrix display device It is possible to obtain the required display brightness. Therefore, during the period in which the matrix type display device is driven in the partial display mode, the driving current of the light emitting element is reduced, so that the deterioration of the luminance with time is suppressed. It becomes more prominent as the driving period in (3) becomes longer. As a result, even when the number of scanning lines of the matrix type display device is increased, it is possible to suppress the deterioration of luminance with time as a whole, and it is possible to realize the same luminance life as that of a display device with a small number of scanning lines. It will be.

When the driving device according to the tenth aspect is adopted, as in the driving device for the matrix type display device according to the eleventh aspect, the control circuit relatively controls the display brightness in the normal display mode. It is possible to perform control so that the display brightness in the partial display mode is relatively low while the display brightness is relatively low. According to this drive device, in the normal display mode in which full-screen display is performed, it is possible to suppress the level of the drive current applied to the light emitting element during scanning with the scanning line, and therefore, as a whole, in order to extend the luminance life. It will be beneficial.

Further, when the driving device according to claim 11 is adopted, as in the driving device for a matrix type display device according to claim 12, the control circuit causes the light emission luminance of the light emitting element at the scanning line scanning to be the normal luminance. By setting the display brightness in the normal display mode to be relatively low and the display brightness in the partial display mode to be relatively high by setting the display mode and the partial display mode to be equal, Overall, it is possible to realize an improvement in the brightness life.

When the driving device according to the tenth aspect is adopted, like the driving device for the matrix type display device according to the thirteenth aspect, the control circuit causes the light emitting element to emit light during scanning line scanning in the normal display mode. Set the brightness relatively high,
Control may be performed to set the light emission luminance of the light emitting element at the time of scanning line scanning in the partial display mode to be relatively low. When such a control is performed, the level of the drive current applied to the light emitting element during the scanning line scanning can be suppressed in the partial display mode. Therefore, overall, it is possible to extend the luminance life. It will be beneficial.

When the driving device according to claim 13 is adopted, like the driving device for the matrix type display device according to claim 14, the control circuit causes the light emitting element to emit light during scanning line scanning in the normal display mode. By setting the brightness relatively high and setting the emission brightness of the light emitting element during scanning line scanning in the partial display mode relatively low, the display brightness in the normal display mode and the display brightness in the partial display mode are equal to each other. Level control may be performed, and this also makes it possible to improve the brightness life as a whole.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION (First Embodiment) A first embodiment of the present invention will be described below with reference to FIGS. FIG. 1 shows the entire electrical configuration by combining functional blocks. In FIG. 1, an organic EL panel 11 (corresponding to a matrix type display device) is modularized together with a drive circuit 12, a control circuit 13 and these power supply circuits 14. Although not specifically shown,
This organic EL panel 1 has the same configuration as the organic EL display device shown in FIG. 6, and has a plurality of anode lines arranged in a matrix (for example, M × N: M, N is an integer of 2 or more). Further, a light emitting element is formed at each intersection of the cathode line and the cathode line, and one of the anode line and the cathode line (for example, cathode line) is a scanning line and the other (for example, an anode line) is a signal line. At the time of driving the organic EL panel 1 as described above, the M row scanning lines are periodically scanned by the row driver 12a in the driving circuit 12, and a desired signal line among the N signal lines is formed in the driving circuit 12. A current signal is applied from the column driver 12b to cause the light emitting element formed at the intersection of the scanning line and the signal line to emit light.

The control circuit 13 includes an image data receiving section 13
a, the image memory 13b, the scanning duty calculation unit 13c,
The drive data generation unit 13d is included. The image data receiving unit 13a is an external device (such as an image processing circuit).
The image data sent from the
Store in b. Note that the image data is data for M rows × N columns corresponding to the organic EL panel 1, and is on / off gradation data for a binary image in this embodiment.

The scanning duty calculation unit 13c reads out the image data stored in the image memory 13b, and for every M scanning lines in the image data for one scanning cycle (for one frame), which one of the light emitting elements on the scanning line is present. It is determined whether one or more of them are turned on (emits light), all the light emitting elements on the scanning line are off (non-emitter), or
Find (≦ M).

The drive data generator 13d supplies image data (m rows × N columns, corresponding to only the scanning lines determined as above).
(ON / OFF gradation) is read from the image memory 13b, and drive data to be given to the drive circuit 12 is generated based on the image data. At the time of generating this data, the drive data generating unit 13d obtains the drive duty ratio of the scanning line, the scanning period, the required light emission luminance during scanning, and the level of the driving current (current signal) during scanning by the following calculations. .

A. The drive duty ratio of the scanning line is 1 / m based on the number of scanning lines m determined by the scanning duty calculation unit 13c. b. Assuming that the scanning period of each scanning line in the state where the driving duty ratio of the scanning line is 1 / M (the state of scanning all the scanning lines: the same driving method as the conventional one) is T [second], the driving duty ratio is 1 / M. The scanning period T ′ of each scanning line when m is T × (M
/ M) [seconds]. c. On the scanning line when the driving duty ratio is 1 / m with respect to the light emission luminance L [cd / m ² ] of the light emitting element on the scanning line in the state where the driving duty ratio of the scanning line is 1 / M (the same driving method as in the past) The light emission luminance L ′ of the light emitting element is L × (m /
M) [cd / m ² ]. d. Under the general assumption that the light emission luminance is proportional to the drive current, the drive current I at the time of scanning each light emitting element to be driven in the state where the drive duty ratio of the scanning line is 1 / M (the same drive method as in the past). Drive duty ratio is 1 compared to [A]
The drive current I ′ at the time of scanning the light emitting element to be driven at / m is I × (m / M) [A].

The drive data generator 13d transmits the drive data generated as described above to the drive circuit 12, and the drive circuit 12 outputs a scanning signal from the row driver 12a according to the received drive data. At the same time, a current signal is output from the column driver 12c, and the organic EL panel 11 is driven by these outputs.

According to this embodiment thus constructed, if there is a scanning line in which the light emitting element to be driven does not exist in the scanning cycle of the M scanning line group of the organic EL panel 11, scanning is performed. The number of scanning lines is from M in normal times,
The number of scanning lines including the light emitting element to be driven is reduced to m. That is, when there is a scanning line in which the light emitting element to be driven does not exist in the scanning cycle of the scanning line group, the scanning of the scanning line in which the light emitting element does not exist is prohibited. Control is performed to reduce the number of scanning lines per scanning cycle and extend the scanning period for the scanning line in which the light emitting element to be driven exists. Therefore, the driving duty ratio of the scanning line scanned in the state where such control is performed becomes large.

Here, in FIG. 2, in order to make it easy to understand the difference between the conventional driving method and the driving method of the present embodiment, an image example displayed on the organic EL panel 11 (conventional: (a), the present embodiment). Example: (d)), emission brightness of the light emitting element in each scanning period (conventional: (b), this example (e)), drive current level (conventional: (c), this example: (f)). ) Is shown schematically. In FIG. 2, an organic EL having M scanning lines
Shape C as shown in (a) and (d) of panel 11
In the case of displaying (the number of scanning lines including the light emitting element to be driven is m), conventionally, even for the scanning lines where the light emitting element to be driven does not exist (the (M-m) scanning lines not corresponding to the shape C). Since scanning is performed, M scanning lines are scanned in one scanning cycle. Therefore, the scanning period T of each scanning line becomes relatively short as shown in (b), and the driving duty ratio of the scanning line becomes 1 / M. As a result, since it becomes necessary to relatively increase the light emission luminance of each light emitting element during scanning, the drive current I flowing through them also increases proportionally as shown in (c).

On the other hand, in the driving method according to the present embodiment, the number of scanning lines per scanning cycle is reduced to m, so that the scanning period T ′ (= T × (M / m )
As shown in (d), the [second] becomes longer than that in the conventional method, and the driving duty ratio of the scanning line is increased to 1 / m. As a result, since it is not necessary to relatively increase the light emission luminance of each light emitting element during scanning, the drive current I ′ (= I × (m / M) [A]) flowing through them is also shown in (f). It will decrease proportionally.

In short, according to the present embodiment, when there is a scanning line in which the light emitting element to be driven does not exist (see, for example, FIG.
In the case of displaying the shape C as shown in (a) and (d)), since the drive duty ratio when scanning the scanning line becomes large, the light emission of the light emitting element that emits light in response to the scanning of the scanning line. Even when the luminance is reduced, that is, when the level of the current signal (driving current of the light emitting element) given to the signal line is reduced, the display luminance required in the organic EL panel 11 can be obtained. As a result of reducing the drive current of the light emitting element in this way, even when the number of scanning lines of the organic EL panel 11 increases, deterioration of luminance over time is suppressed, and a luminance life equivalent to that of an organic EL panel having a small number of scanning lines is obtained. It will be feasible.

(Second Embodiment) FIG. 3 shows a second embodiment of the present invention, and only the parts different from the first embodiment will be described below. Since the hardware configuration of the second embodiment is the same as that of FIG. 1 in the first embodiment, refer also to FIG. In the second embodiment, the image data for M rows × N columns which the image data receiving unit 13a receives from the external device and stores in the image memory 13b has K gradations for a gradation display image of a plurality of stages. The data. Further, when the organic EL panel 1 is driven based on this image data, M row scanning lines are periodically scanned by the row driver 12a in the drive circuit 12, and a desired signal line among N signal lines is selected. Column driver 12 in drive circuit 12
b) selectively applying a current signal having a pulse width of a plurality of steps from b to cause the light emitting element formed at the intersection of the scanning line and the signal line to emit light at a plurality of gradation levels according to the current signal pulse width. become.

The scanning duty calculator 13c reads out the image data stored in the image memory 13b, and for each scanning line, the maximum value k of the gradation level of the light emitting element on the scanning line.
Seek _{1 ~k M.} Then, set the respective scanning periods of the M-th scanning line from the first, so that the maximum value k ₁ to k _M period proportional to the gray level of the light emitting element of each scan line. However, one scanning cycle is the same as in the first embodiment.
(T × M when the scanning period of each scanning line is T 1). Therefore, the scanning period T ′ _m of the m-th scanning line has a value represented by the following expression (1).

[0034]

[Equation 1] In this equation (1), when km = 0, _T'm = 0
Becomes That is, when the gradation levels of all the light emitting elements on the m-th scanning line are zero, the scanning line is not scanned, which is the same as in the first embodiment.

The drive data generation unit 13d follows the procedure described below based on the calculation result of the scanning duty calculation unit 13c and the image data stored in the image memory 13b, and the required light emission luminance at the time of scanning line scanning. , Calculate the level of the drive current (current signal) during scanning.

That is, the light emission luminance L'm when scanning the light emitting element corresponding to the maximum gradation level km of the mth scanning line
[Cd / m ² ] is the luminance of light emitted during scanning by the conventional method (luminance L × (km / K considering the gradation level when the luminance at the full gradation level is L [cd / m ² ]). ) [Cd / m ² ]) and the following equation (2).

[0037]

[Equation 2] From this equation (2), the following equation (3) is obtained.

[Equation 3] Since there is no factor for the m-th scanning line on the right side of this equation (3), the light emission luminance L'm [cd during scanning of the light emitting element corresponding to the maximum gradation level of each scanning line is present.
/ M ² ] is constant for every scan line. Therefore, L'm will be referred to as L'in the following description. As a result, the following equation (4) is obtained.

[0038]

[Equation 4] From this equation (4), the following can be understood. That is, only when the maximum value km of the gradation level of the light emitting element on the m-th scanning line is all full gradation (km = K (m = 1 to M)), the driving method of the present embodiment is used. The light emission luminance L ′ at the time of scanning each scanning line coincides with the luminance L at the full gradation level, so that the effect of the first embodiment cannot be obtained. However, when the organic EL panel 11 is actually driven,
It is not always the case that the maximum value of the gradation levels km of the light emitting elements on the scanning line km is full gradation.
In other states, the relation L '<L is established, so that the same effect as that of the first embodiment can be obtained as described later.

Here, under the assumption that the light emission brightness of the light emitting element is proportional to the drive current, the drive current I'required in this embodiment is different from the drive current I [A] required in the conventional drive method. Can be expressed by the following equation (5).

[0040]

[Equation 5] By controlling the pulse width of the drive current (current signal) applied during the scanning period to each light emitting element having a gradation level other than the maximum gradation level km on the scanning line,
It is assumed that a predetermined brightness and gradation level are obtained. in this case,
The pulse width Pij applied to the light emitting element in the i-th row and the j-th column is
It is obtained by the following equation (6).

[0041]

[Equation 6] On the other hand, the drive data generation unit 13d determines the image data (m rows x
(N columns, K gradations) are read out from the image memory 13b, and drive data corresponding to the image data is generated in consideration of the maximum drive current at the time of scanning each scanning line during the scanning period calculated according to the procedure described above. , To the drive circuit 12. The drive circuit 12 outputs a scanning signal from the row driver 12a and a current signal from the column driver 12c according to the received drive data. At this time, the drive current applied to each light emitting element and its pulse width are expressed by the above equations (5) and (6).

According to this embodiment having such a configuration, each light emitting element emits light at a plurality of gradation levels according to image data given from the outside. In this case, the scanning period of each scanning line in one scanning cycle of the scanning line group is set to the maximum gradation level km of the driving target light emitting element existing on the scanning line.
The control is performed so that the period is proportional to.
Therefore, for example, when the light emitting element to be driven does not exist on the scanning line, the maximum gradation level km of the light emitting element to be driven is considered to be zero, and scanning is performed on the scanning line where the light emitting element does not exist. I don't know. Further, with respect to the scanning line in which the light emitting element to be driven is present, the scanning period is controlled to be short when the maximum gradation level km of the light emitting element to be driven is relatively low. Or if there is a scan line in which the above-mentioned scanning is not performed, the other scan line, that is, the scan line in which the light emitting element to be driven in which the maximum gradation level km is relatively high exists. The scanning period will be extended. Therefore, the driving duty ratio of the scanning line in which the light emitting element is required to be displayed at a relatively high gradation level is large.

Here, in FIG. 3, in order to make it easy to understand the difference between the conventional driving method and the driving method of this embodiment, an example of an image displayed on the organic EL panel 11 (conventional: (a), this embodiment). Example: (d)), emission brightness of the light emitting element in each scanning period (conventional: (b), this example (e)), drive current level (conventional: (c), this example: (f)). ) Is shown schematically. In FIGS. 10A and 10D, the region 11a has a gradation level of zero (a state in which there is no light emitting element that emits light on the scanning line,
The region 11b shows a state where the gradation level is medium and the region 11c shows a state where the gradation level is maximum.

In FIG. 3, when three-step gradation display as shown in (a) and (d) is performed in the organic EL panel 11 having M scanning lines, conventionally, all the scanning lines (M Book) will be scanned. Therefore, the scanning period T of each scanning line becomes relatively short as shown in (b), and the driving duty ratio of the scanning line becomes 1 / M. As a result, since it becomes necessary to relatively increase the light emission luminance of each light emitting element during scanning, the drive current I flowing through them also increases proportionally as shown in (c).

On the other hand, in the driving method according to the present embodiment, when there is no light emitting element to be driven on the scanning line, the scanning line (scanning line in the area 11a) is not scanned, and the driving is performed. A scanning line (scanning line in the region 11b) having a relatively low maximum gradation level km of the target light emitting element is controlled so that the scanning period is shortened, and conversely, the maximum gradation of the driving target light emitting element is controlled. With respect to the scanning line having a relatively high level km (the scanning line in the area 11c), the scanning period T'is controlled to be long as shown in (e). As a result, since it is not necessary to relatively increase the light emission luminance of each light emitting element during scanning, the drive current I ′ (= I × (m / M) [A]) flowing through them is also shown in (f). It will decrease proportionally.

In short, according to the present embodiment, for a scanning line in which the maximum gradation level km of the light emitting element to be driven is high, the driving duty ratio when scanning the scanning line becomes large, so that scanning line concerned Even when the light emission brightness of the light emitting element that emits light in response to the scanning is reduced, that is, when the level of the current signal (driving current of the light emitting element) given to the signal line is reduced, the display required in the organic EL panel 11 is reduced. It is possible to obtain brightness. As a result of reducing the drive current of the light emitting element in this way, even when the number of scanning lines of the organic EL panel 11 increases, deterioration of luminance over time is suppressed, and a luminance life equivalent to that of an organic EL panel having a small number of scanning lines is obtained. It will be feasible.

(Third Embodiment) FIGS. 4 and 5 show a third embodiment of the present invention. Hereinafter, only parts different from the first and second embodiments will be described. . In FIG. 3, which shows the overall electrical configuration by combining functional blocks, in this embodiment, a control circuit 15 is provided instead of the control circuit 13 in the first and second embodiments. The image data receiving unit 15 in the control circuit 15
a is image data (M rows × N) sent from an external device.
The column, K gradation) is received and stored in the image memory 15b.
The drive data generator 15c reads out image data from the image memory 15b in accordance with a display mode designated from the outside to generate drive data, and outputs the drive data to the drive circuit 12.
Give to.

Here, the display mode is the organic E
A "low-luminance full screen mode" (corresponding to the normal display mode in the present invention) in which all the scanning lines of the L panel 11 are scanned to display the entire screen with a relatively low emission luminance, and only a specific scanning line group is displayed. A “high-brightness sub-screen mode” (corresponding to the partial display mode in the present invention) in which a screen is displayed by scanning and using only a predetermined range with a relatively high emission brightness is set.

When the display mode is the low-luminance full screen mode, the drive data generator 15c sequentially reads out all the image data for one frame (M rows × N columns, K gradations) from the image memory 15b. In addition, the drive data generation unit 15c
When the display mode is the high-brightness sub-screen mode, the image data (m
(Row × N column, K gradation) is read. Note that m <M. Here, if the scanning period of each scanning line in the low-luminance full screen mode is T [seconds] and the scanning period of each scanning line in the high-luminance sub-screen mode is T '[seconds], then T' = T x (M /
m) and T ′> T.

The drive data generator 15c generates drive data under the following conditions based on the read image data. That is, the maximum light emission brightness of each light emitting element at the time of scanning line scanning in the low brightness full screen mode is L [cd / m
² ], the maximum light emission brightness of each light emitting element at the time of scanning line scanning in the high brightness sub-screen mode is also L [cd / m
² ]. Further, the maximum drive current of each light emitting element at the time of scanning line scanning in the low brightness full screen mode is I
In the case of [A], the maximum drive current of each light emitting element during scanning line scanning in the high-brightness sub-screen mode is also I [A]
Set to. The drive circuit 12 that has received such drive data follows the drive data from the row driver 12a.
Output a scanning signal from the column driver 12c
Outputs a current signal from.

According to the present embodiment configured as described above, as the display mode of the organic EL panel 11, the low-luminance full-screen mode in which all the scanning lines are scanned and the entire screen is displayed with a relatively low display brightness is specified. And a high-brightness sub-screen mode in which only the scanning line group is scanned and display using only a predetermined range is performed with a relatively high display brightness, and the emission brightness during scanning line scanning is set to a low-brightness full screen mode. Are set to the same in high brightness sub-screen mode. As a result, in the high-brightness sub-screen mode, the scanning period of the scanning line to be scanned is extended, the drive duty ratio of the scanning line to be scanned is increased, and the drive current for obtaining the required emission brightness is obtained. Is suppressed.

Here, in FIG. 5, an example of an image displayed on the organic EL panel 11 (low-luminance full screen mode: (a)) is shown in order to make it easy to understand the driving method of this embodiment in which two kinds of display modes are set. , High brightness sub-screen mode:
(D)), emission brightness of the light emitting element in each scanning period (low brightness full screen mode: (b), high brightness sub-screen mode (e)), drive current level (low brightness full screen mode:
(C), high-brightness sub-screen mode: (f)) is schematically shown. In FIG. 5, in the low-luminance full-screen mode, each scanning period T of the M scanning lines is shortened and the driving duty ratio is reduced, but the driving current I is suppressed. Further, in the high-brightness sub-screen mode, each scanning period T ′ of the m scanning lines is extended, so that a high emission brightness can be obtained even with the same current I.

In short, according to the present embodiment, the driving current of the light emitting element is reduced in each of the periods in which the organic EL panel 11 is driven in the low-luminance full screen mode and the high-luminance sub-screen mode. The deterioration over time is suppressed. As a result, even when the number of scanning lines of the organic EL panel 11 increases, it is possible to suppress the deterioration of the luminance over time and achieve a luminance life equivalent to that of a display device having a small number of scanning lines.

(Other Embodiments) In addition, the present invention is not limited to the above-described embodiments, but can be modified or expanded as described below. In the third embodiment, the "low-luminance full screen mode" in which the entire screen is displayed with a relatively low emission brightness is set as the normal display mode, and only the predetermined range of the screen is used as the partial display mode. Although the configuration is such that the "high brightness sub-screen mode" with high emission brightness is set, it is not necessary to set the emission brightness in the full screen mode to low brightness. When the light emission luminance in the normal display mode in which the entire screen is used is increased as described above, the driving current of the light emitting element increases to the same level as the conventional maximum, so that the light emission luminance is expected to decrease with time. However, in the period driven in the partial display mode, the driving current of the light emitting element is reduced, so that the deterioration of the emission luminance with time is suppressed, and such a suppressing effect is obtained in the driving period in the partial display mode. Becomes more prominent as is relatively longer. As a result, even when the number of scanning lines of the matrix type display device is increased, it is possible to suppress deterioration in luminance over time as a whole.
It is possible to realize the same brightness life as that of a display device having a small number of scanning lines. Therefore, for example, even if the light emission luminances in the normal display mode and the partial display mode are set equal,
Overall, it is possible to improve the brightness life.

When the normal display mode and the partial display mode are set, the emission brightness of the light emitting element during the scanning line scanning in the normal display mode is set to be relatively high, and the scanning line scanning during the partial display mode is set. You may perform the control which sets the light emission brightness of a light emitting element relatively low. When such control is performed, it is possible to suppress the level of the drive current applied to the light emitting element during the scanning line scanning in the partial display mode, and therefore, it is useful in extending the luminance life as a whole. Becomes

Further, the light emission luminance of the light emitting element is set relatively high during scanning line scanning in the normal display mode, and
By setting the light emission luminance of the light emitting element at the time of scanning line scanning in the partial display mode to be relatively low, each display luminance in the normal display mode and the partial display mode may be set to the same level. Even if it sees as a whole, the improvement of the brightness life can be realized.

As an example of the matrix type display device, organic E
Although the L panel 11 is taken as an example, it can be widely applied to other matrix type display devices such as a display panel using a light emitting diode as a light emitting element.

[Brief description of drawings]

FIG. 1 is a functional block diagram of an electrical configuration showing a first embodiment of the present invention.

[Fig. 2] Operation explanatory diagram

FIG. 3 is a view corresponding to FIG. 2 showing a second embodiment of the present invention.

FIG. 4 is a view corresponding to FIG. 1 showing a third embodiment of the present invention.

FIG. 5 is a view corresponding to FIG.

FIG. 6 is an equivalent circuit configuration diagram for explaining a driving method of a conventional example.

FIG. 7: Luminance life characteristic diagram

[Explanation of symbols]

Reference numeral 11 denotes an organic EL panel (matrix type display device), 12
Is a drive circuit, and 13 and 15 are control circuits.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H05B 33/14 H05B 33/14 AF term (reference) 3K007 AB11 BA06 DB03 GA04 5C080 AA06 AA07 BB05 DD29 EE19 EE29 FF12 GG09 GG12 GG17 JJ02 JJ05

Claims (14)

[Claims] 1. A matrix in which light emitting elements are formed at intersections of a plurality of anode lines and cathode lines arranged in a matrix, one of the anode lines and the cathode lines being a scanning line and the other being a signal line. A driving method for a type display device, in which a current signal is applied to a desired signal line while scanning a scanning line periodically to cause a light emitting element formed at an intersection of the scanning line and the signal line to emit light. In the method, in the case where there is a scan line in which a light emitting element to be driven does not exist in one scan cycle of the scan line, scanning for a scan line in which the light emitting element does not exist is prohibited, and thus a scan line per scan cycle. A method for driving a matrix type display device, characterized in that control is performed to reduce the number and extend a scanning period for a scanning line in which a light emitting element to be driven exists. 2. A matrix in which light emitting elements are formed at respective intersections of a plurality of anode lines and cathode lines arranged in a matrix, one of the anode lines and the cathode lines being a scanning line and the other being a signal line. A driving method for a display device, wherein a light emitting element formed at an intersection of a scanning line and a signal line by periodically scanning the scanning line and applying a level-adjustable current signal to a desired signal line In the driving method for emitting light at a plurality of gradation levels according to the current signal level, the scanning period of each scanning line in one scanning cycle of the scanning line is set to the maximum floor of the driving target light emitting elements existing on the scanning line. A method for driving a matrix type display device, characterized in that control is performed so that a period is proportional to the adjustment level. 3. A matrix in which light emitting elements are formed at respective intersections of a plurality of anode lines and cathode lines arranged in a matrix, one of the anode lines and the cathode lines being a scanning line and the other being a signal line. A driving method for a type display device, in which a current signal is applied to a desired signal line while scanning a scanning line periodically to cause a light emitting element formed at an intersection of the scanning line and the signal line to emit light. In the method, as a display mode of the matrix type display device, a normal display mode in which all scanning lines are scanned to display a full screen, and a portion in which only a specific scanning line group is scanned to perform display using only a predetermined range A driving method of a matrix type display device, characterized in that by setting the display mode, the scanning period of the scanning lines scanned in the partial display mode is extended. 4. The driving method for the matrix type display device according to claim 3, wherein the display brightness in the normal display mode is relatively low and the display brightness in the partial display mode is relatively high. A method of driving a matrix type display device, comprising: 5. The method for driving a matrix type display device according to claim 4, wherein the light emission brightness of the light emitting element during scanning line scanning is set to be equal in the normal display mode and the partial display mode. A method for driving a matrix type display device, characterized in that control is performed such that display luminance in a display mode is relatively low and display luminance in a partial display mode is relatively high. 6. The driving method for a matrix type display device according to claim 3, wherein the light emission luminance of the light emitting element is set to be relatively high during scanning line scanning in the normal display mode, and scanning in the partial display mode is performed. A driving method of a matrix type display device, characterized in that the emission luminance of a light emitting element during line scanning is set relatively low. 7. The driving method of the matrix type display device according to claim 6, wherein the light emission luminance of the light emitting element at the time of scanning line scanning in the normal display mode is set relatively high, and in the partial display mode. A matrix type display device characterized in that the display brightness in the normal display mode and the display brightness in the partial display mode are set to the same level by setting the light emission brightness of the light emitting element at the time of scanning line scanning relatively low. Driving method. 8. A matrix in which light emitting elements are formed at intersections of a plurality of anode lines and cathode lines arranged in a matrix, one of the anode lines and the cathode lines being a scanning line and the other being a signal line. A drive device for a flat-panel display device, in which a current signal is applied to a desired signal line while scanning a scanning line periodically to cause a light emitting element formed at an intersection of the scanning line and the signal line to emit light. In a driving device including a circuit, the control circuit scans a scanning line in which the light emitting element does not exist when there is a scanning line in which the light emitting element to be driven does not exist in the scanning cycle of the plurality of scanning lines. By prohibiting, the number of scanning lines per scanning cycle is reduced, and control is performed to extend the scanning period for the scanning line in which the light emitting element to be driven exists. Drive of the scan-type display device. 9. A matrix in which light emitting elements are formed at intersections of a plurality of anode lines and cathode lines arranged in a matrix, one of the anode lines and the cathode lines being a scanning line and the other being a signal line. A driving device for a display device, wherein a light emitting element is formed at an intersection of a scanning line and a signal line by periodically scanning the scanning line and applying a level-adjustable current signal to a desired signal line. In a drive circuit including a control circuit for emitting light at a plurality of gradation levels according to the current signal level, wherein the control circuit controls a scanning period of each scanning line in one scanning cycle of the plurality of scanning lines, A drive device for a matrix type display device, which is controlled so as to have a period proportional to a maximum gradation level of a drive target light emitting element existing on the scanning line. 10. A light emitting device is formed at each intersection of a plurality of anode lines and cathode lines arranged in a matrix,
A driving device for a matrix type display device in which one of the anode line and the cathode line is a scanning line and the other is a signal line, and a current signal is supplied to a desired signal line while periodically scanning the scanning line. In a driving device provided with a control circuit that emits light emitting elements formed at intersections of the scanning lines and the signal lines, the control circuit scans all scanning lines as a display mode of the matrix display device. By setting the normal display mode in which the entire screen is displayed and the partial display mode in which only a specific scanning line group is scanned and display is performed using only a predetermined range, the scanning lines scanned in the partial display mode are set. 2. A drive device for a matrix type display device, which is characterized in that the scanning period of (1) is extended. 11. The drive device for a matrix type display device according to claim 10, wherein the control circuit relatively lowers display brightness in the normal display mode and relatively reduces display brightness in the partial display mode. A device for driving a matrix type display device, which is characterized in that it is controlled to be higher in height. 12. The driving device for a matrix type display device according to claim 11, wherein the control circuit sets the light emission brightness of the light emitting element during the scanning line scanning to be equal in the normal display mode and the partial display mode. By doing so, the drive device of the matrix type display device is characterized in that the display brightness in the normal display mode is relatively low and the display brightness in the partial display mode is relatively high. 13. The drive device for a matrix type display device according to claim 10, wherein the control circuit sets a relatively high light emission luminance of a light emitting element during scanning line scanning in the normal display mode, A drive device for a matrix type display device, characterized in that the light emission luminance of a light emitting element is set relatively low during scanning line scanning in a display mode. 14. The driving device for a matrix type display device according to claim 13, wherein the control circuit sets the light emission luminance of the light emitting element during scanning line scanning in the normal display mode to be relatively high.
By setting the emission brightness of the light emitting element at the time of scanning line scanning in the partial display mode to be relatively low, each display brightness in the normal display mode and the partial display mode is controlled to the same level. Drive device for matrix type display device.