JP4942310B2 - Display device - Google Patents

Description

  The present invention relates to a display device, and more particularly to a display device including a plurality of display color pixels.

  In recent years, an organic EL (Electro Luminescence) display has been developed, and for example, adopting an organic EL display in a mobile phone is being studied. As a driving method of the organic EL display, a passive matrix driving method in which time-division driving is performed using a scanning electrode and a data electrode, and a TFT (Thin Film Transistor) is disposed in each pixel, and light emission of each pixel is 1 vertical. There is an active matrix driving method which is maintained over a scanning period.

  Since the active matrix driving method can reliably operate only the target pixel, it can achieve high image quality and high contrast and has a high response speed compared to the passive matrix driving method. .

In organic EL displays, pixels of three colors of red, green, and blue are usually used for color display. Recently, red, green, and green are used as a method for reducing power consumption when performing white display or intermediate color display. In addition, a method of displaying an image with four colors in which white is added to blue has been proposed (see, for example, Patent Document 1). When displaying an image in three colors of red, green, and blue, the power consumption is greatest when performing white display where each color must be emitted simultaneously, but by using an organic EL element that emits white light, the power consumption Can be reduced.
US Patent Application Publication No. 2002/0186214

  By the way, when driving an organic EL element using a TFT, it is necessary to consider an operation margin in order to cause the organic EL to emit light at a desired brightness with a stable brightness. The operation margin will be described with reference to FIG. FIG. 1A is a diagram showing a drive circuit for an organic EL element OEL using TFTs. FIG. 1B is a diagram illustrating an IV characteristic curve of the TFT and an IV characteristic curve of the organic EL element OEL. The horizontal axis of the graph represents the relative potential of the node A with respect to the potential Vdd of the TFT source. The vertical axis of the graph represents the drain-source current Ids of the TFT and the current of the organic EL element OEL.

  When the video signal voltage Vsig is applied to the gate electrode of the TFT and the voltage Vgs is generated between the gate and the source of the TFT, a drain-source current Ids flows. When the drain-source current Ids flows through the organic EL element OEL, the organic EL element OEL emits light.

  A curve 40 in FIG. 1B shows the relationship between the drain-source voltage Vds and the drain-source current Ids when the gate-source voltage Vgs in the TFT is applied. When the absolute value of Vds is increased, Ids increases, but Ids hardly changes even if the absolute value of Vds is increased with a certain voltage as a boundary. A region where Ids increases when the absolute value of Vds is increased is called a linear region 46, and a region where Ids hardly changes even when the absolute value of Vds is increased is called a saturated region 44. Ids in saturation region 44 is referred to as saturation current Idss. The saturation current Idss can be changed by changing the gate voltage of the TFT. The voltage at the boundary where the linear region 46 changes to the saturation region 44 is referred to as a pinch-off voltage Vp.

  A curve 42 in FIG. 1B is an IV characteristic curve of the organic EL element OEL. The intersection of the curve 40 and the curve 42 is the operating point of the circuit of FIG. 1A. When the gate voltage of the TFT is changed and Ids changes, the operating point moves on the curve 42. The voltage at the operating point is referred to as the operating point voltage Vq.

  The operating margin is a difference between the pinch-off voltage Vp and the operating point voltage Vq. When driving an organic EL element, the drive circuit is usually designed so that the operating point is located in the saturation region 44. At this time, it is desirable that the operating point voltage Vq is as far as possible from the pinch-off voltage Vp, that is, the operating margin is as wide as possible. For example, when the drive voltage (Vdd-CV) is reduced due to the variation in the voltage generated by the power supply circuit, the curve 42 shifts to the right as shown by the curve 48, and the operating point deviates from the saturation region 44. There is a possibility of being located in the linear region 46. Further, there is a possibility that the operating point is located in the linear region 46 due to the change in characteristics of the organic EL element OEL over time. When the operating point is in the linear region 46, Ids changes greatly due to a slight change in driving voltage (Vdd-CV) or a change in characteristic curve of the organic EL element OEL due to a temperature change. OEL cannot emit light with high accuracy and stable brightness.

  In an organic EL display using white pixels, since white pixels do not require a color filter, the light emission efficiency is higher than that of other colors, and light is emitted to a desired luminance with a current smaller than that of pixels other than white. be able to. When the current passed through the organic EL element OEL is reduced, the TFT has an IV characteristic curve as shown by a curve 54, so that the operation margin is widened. For this reason, the operation margin of white pixels tends to be wider than the operation margin of non-white pixels.

  The operation margin can be widened by increasing the drive voltage (Vdd-CV). When the operation margins of the pixels of the different colors are different, the drive voltage (Vdd-CV) needs to be set according to the pixel of the color having the narrowest operation margin in order to obtain stable light emission in the pixels of all colors. . When the difference between the operation margins of the pixels of each color is large, a high drive voltage (Vdd-CV) is applied even to the pixels of the color for which a sufficient operation margin is ensured, and the power consumption of the entire organic EL display Will increase.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a display device that reduces power consumption while ensuring an operation margin of pixels.

  In order to solve the above problems, a display device according to an embodiment of the present invention includes a pixel that includes a self-light-emitting element that emits light when supplied with a current, and a current driving element that controls a supply current to the self-light-emitting element. A plurality of display color pixels including white, and the current drive capability of the current drive elements in the pixels other than white is greater than the current drive capability of the current drive elements in the white pixels. It is a feature.

  According to this aspect, by setting the current drive capability of the current drive element in the non-white pixel to be larger than the current drive capability of the current drive element in the white pixel, the operation margin of the non-white pixel is expanded. And the difference from the operation margin of the white pixel can be reduced. As a result, it is not necessary to supply a high driving voltage as compared with the case where the current driving elements of all the pixels have the same current driving capability, which is effective in reducing the power consumption of the entire display device. In addition, since the operation margin other than white is widened, the organic EL element can emit light with high accuracy and stability.

  Another embodiment of the present invention is also a display device. The display device is a display device including pixels each including a self-light-emitting element that emits light when supplied with a current, and a current driving element that controls a supply current to the self-light-emitting element, and has a plurality of display colors. The current drive capability of the current drive element is set so that the difference between the operation margins of the pixels of each color is provided.

  According to this aspect, the current drive capability of the current drive element is set so that the difference between the operation margins of the pixels of the plurality of display colors becomes small. For this reason, when the difference in the operating margin is large, the drive voltage needs to be set high in accordance with the color with the narrow operating margin, but it is necessary to supply a high driving voltage by reducing the difference in the operating margin. This is effective in reducing the power consumption of the entire display device.

  According to the present invention, it is possible to provide a display device with reduced power consumption while ensuring an operation margin of pixels.

<First Embodiment>
FIG. 2 is a diagram illustrating a pixel layout of the display device according to the first embodiment. As shown in FIG. 2, the display device 10 according to the present embodiment includes four color pixels, which are a red pixel A1, a green pixel A2, a blue pixel A3, and a white pixel A4. An image constituent unit 12 is constituted by four pixels A1, A2, A3, and A4 arranged side by side.

  By providing the white pixel A4, when displaying white, not all red, green, and blue pixels are lit, but only white pixels need to be lit, thereby reducing power consumption. Can do. In the display device 10, image constituent units 12 are arranged in a matrix.

  As shown in FIG. 2, each of the pixels A1, A2, A3, and A4 is a region surrounded by a gate line SL arranged extending in the row direction and a data line DL arranged extending in the column direction. Formed. Each of the pixels A1, A2, A3, and A4 includes an organic EL element OEL, a driving TFT2, a switching TFT1, and a storage capacitor SC. The organic EL element OEL is a self-light-emitting element that emits light when supplied with current, and the driving TFT 2 is a current-driven element that controls a supply current to the self-light-emitting element.

  FIG. 3 is an equivalent circuit diagram of one pixel A1, A2, A3, and A4 in the display device 10 shown in FIG. The switching TFT 1 is an n-channel TFT, and the driving TFT 2 is a p-channel TFT. A gate line SL is connected to the gate of the switching TFT 1, and a data line DL is connected to its drain. The source of the switching TFT 1 is connected to the gate of the driving TFT 2. The source of the switching TFT 1 is also connected to an electrode on one end side of the storage capacitor SC. A potential Vss is applied to the electrode on the other end side of the storage capacitor SC. A potential Vdd is supplied from the power supply line PVDD to the source of the driving TFT 2. The drain is connected to the anode of the organic EL element OEL. A potential CV is applied to the cathode of the organic EL element OEL. A potential difference (Vdd-CV) between Vdd and CV is a pixel driving voltage.

  When the gate line SL connected to the gate of the switching TFT 1 is at a low level, the switching TFT 1 is turned on. Therefore, when the video signal voltage Vsig is applied from the data line DL to the drain of the switching TFT 1, It is held by the holding capacitor SC. By changing the value of Vsig, the drain-source current Ids of the driving TFT 2 can be changed. Ids is a drive current for the organic EL element OEL. The organic EL element OEL is supplied with a driving current Ids via the driving TFT 2 and emits light with a desired luminance.

  FIG. 4 schematically shows a cross section of the display device 10 according to the first embodiment. As shown in FIG. 4, three colors of red, green, and blue are obtained by color-converting white light from the organic EL light emitting layer 17 that emits white light with a red, blue, and green color filter 16. Since the transmittance of the color filter 16 varies depending on the structure and material of the color filter 16, the luminous efficiency varies depending on the color. For white, the white light emitted from the organic EL light emitting layer 17 is used as it is without being transmitted through the color filter 16, so that the light emission efficiency is higher than other colors. The display device 10 according to the embodiment performs full-color display using these four colors.

  As described above, the organic EL element OEL is supplied with the drive current Ids via the drive TFT 2 and changes the luminance according to the value of the drive current Ids. Therefore, the drive TFT 2 that controls the drive current Ids needs to be able to control the drive current Ids with high accuracy according to the value of the video signal voltage Vsig in order to display a high-quality video.

  In order to improve the controllability of the drive current Ids, a wide operation margin must be ensured. The operation margin is a difference between the pinch-off voltage Vp and the operating point voltage Vq as described with reference to FIG. If the operation margin is narrow, the drive current Ids greatly changes due to a slight change in drive voltage (Vdd-CV) or a change in the characteristic curve of the organic EL element OEL due to a temperature change. It is impossible to emit light with high accuracy and stable brightness.

  Since the white pixel A4 does not transmit the color filter, the light emission efficiency is higher than that of the other colors, and the white pixel A4 can emit light with desired current with a smaller current than the pixels of the other colors. When the current flowing through the organic EL element OEL is reduced, the operation margin is widened as described with reference to FIG. Therefore, the operation margin of the white pixel A4 tends to be wider than the operation margins of the non-white pixels A1 to A3.

  The operation margin can be widened by increasing the drive voltage (Vdd-CV). When the operation margins of the pixels of the different colors are different, the drive voltage (Vdd-CV) needs to be set according to the pixel of the color having the narrowest operation margin in order to obtain stable light emission in the pixels of all colors. . For this reason, when pixels with a wide operation margin and narrow pixels are mixed, a color with a sufficient operation margin secured by setting the potential Vdd high or setting the potential CV low according to the narrow pixel. As a result, a high drive voltage (Vdd-CV) is applied to this pixel, and the power consumption of the entire display device 10 increases.

  Therefore, in the first embodiment, the current driving capability of the driving TFT 2 in the pixels A1 to A3 other than white is set to be larger than the current driving capability of the driving TFT 2 in the white pixel A4. In this case, the operation margin of the pixels A1 to A3 other than white can be widened, and the difference from the operation margin of the white A4 pixel is reduced. As a result, it is not necessary to supply a high drive voltage (Vdd-CV) according to a color with a narrow operation margin, which is effective in reducing the power consumption of the entire display device 10. Further, since the operation margin of the pixels A1 to A3 other than white is widened, the organic EL element can be made to emit light stably.

The current driving capability of the driving TFT 2 can be varied for each color by varying at least one of the channel length and the channel width. FIG. 5A is a plan view schematically showing the structure of the driving TFT 2. FIG. 5B is a diagram schematically showing the structure of the driving TFT 2. The drain-source current Ids of the TFT is
Ids = μC _ox W / L {(Vgs−Vth) −Vds / 2} Equation 1
It is represented by Here, μ is the carrier mobility, C _ox is the gate insulating film capacitance, Vds is the drain-source voltage, Vth is the threshold voltage, W is the TFT channel width, and L is the TFT channel length. As can be seen from Equation 1, Ids is proportional to the channel width W and inversely proportional to the channel length L. That is, by appropriately setting the channel width W and the channel length L, the current driving capability of the driving TFT 2 can be changed.

  In order to increase the current driving capability of the driving TFT 2, as can be seen from Equation 1, the channel width W should be as large as possible and the channel length L should be as small as possible. However, if the channel width W is too large, the area of the driving TFT 2 is increased, and the aperture area of the pixel is decreased. Further, when the channel length L is too small, the saturation current Idss becomes unstable in the IV characteristic curve of the driving TFT 2.

  Thus, increasing the current driving capability of the driving TFT 2 to increase the operating margin and reducing the aperture area of the pixel are in a trade-off relationship. The current driving capability of the driving TFT 2 in the pixel is set. In addition, for white pixels that have a high light emission efficiency and can secure a sufficiently wide operation margin even if the current driving capability of the driving TFT 2 is smaller than that of the pixels other than white, considering that the aperture area is reduced, The current driving capability of the driving TFT 2 is set to be smaller than that of pixels other than white.

  An example of the first embodiment is shown by setting specific numerical values. FIG. 6 is a diagram illustrating an IV characteristic curve of the driving TFT 2 and an IV characteristic curve of the organic EL element OEL according to the first embodiment. In the first embodiment, the channel length L of the driving TFT 2 is set so that the current driving capability of the driving TFT 2 in the pixels A1 to A3 other than white is larger than the current driving capability of the driving TFT 2 in the white pixel A4. Set the channel width W. In FIG. 6, the driving TFT 2 of the pixels A1 to A3 other than white is set to have a channel length L = 45 μm and a channel width W = 4.7 μm, and the driving TFT 2 of the white pixel A4 has a channel length L = 50 μm and a channel width. W = 4 μm was set. In the first embodiment, the aperture area ratio of each color pixel is red: green: blue: white = 1: 1: 1: 1.

  FIG. 2 shows a state in which the channel length and the channel width are different between white pixels and non-white pixels. As described above, the channel length L1 of the driving TFT 2 of the pixels A1 to A3 is 45 μm and the channel width is 4.7 μm, and the channel length L2 (50 μm) and the channel width W2 (4 μm) of the driving TFT 2 of the pixel A4 are different. ing. Thereby, the current driving capability of the driving TFT 2 other than the white pixel is made larger than the current driving capability of the driving TFT 2 of the white pixel. Note that by making the channel widths W1 and W2 the same and making the channel length L1 shorter than L2, the current driving capability of the driving TFT 2 other than white is larger than the current driving capability of the driving TFT 2 of the white pixel. Also good. Similarly, by making the channel lengths L1 and L2 the same and making the channel width W1 larger than W2, the current driving capability of the driving TFT 2 other than the white pixel can be made larger than the current driving capability of the TFT 2 of the white pixel. Good.

  In FIG. 6, a curve 60 is an IV characteristic curve of the organic EL element OEL. Since the aperture areas of the pixels of each color are equal, the IV characteristic curve of the organic EL element OEL is the same IV characteristic curve for each color. The horizontal axis of the graph represents the relative potential of the node A with respect to the source potential Vdd of the driving TFT 2 (the potential of the node A -Vdd or the relative potential of the node A when Vdd is 0 V). The potential difference between Vdd and CV is set to 14V. The vertical axis of the graph represents the drain-source current Ids of the driving TFT 2 and the current of the organic EL element OEL.

  A curve 62 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, a curve 64 is an IV characteristic curve of the green and blue pixels A2 and A3, and a curve 66 is a driving of the white pixel A4. It is an IV characteristic curve of TFT2. Each IV characteristic curve can be obtained by appropriately setting the value of Vsig supplied to the gate of the driving TFT. As described above, since the luminous efficiencies of the respective colors are different, the currents required to obtain a desired luminance are also different. In the first embodiment, the current required to obtain a certain luminance value is set as red = 2.66 μA, green = 1.38 μA, blue = 1.38 μA, and white = 1.25 μA. This means that, for example, red requires 2.66 μA and green requires 1.38 μA to obtain a certain luminance value.

  As described above, the operation margin is a difference between the pinch-off voltage Vp and the operating point voltage Vq. The intersection of the curve 60 and the curve 62 is a red operating point 68, the intersection of the curve 60 and the curve 64 is a green and blue operating point 70, and the intersection of the curve 60 and the curve 66 is a white operating point 72. In addition, the pinch-off voltage is a voltage at the boundary where the IV characteristic curve of the driving TFT 2 changes from the linear region to the saturation region. In this specification, the pinch-off voltage Vp is 5% lower than the saturation current Idss. This will be described as the voltage when

  As shown in FIG. 6, the red operation margin is 1.56 V (Vp = −2.84 V, Vq = −4.40 V), and the green and blue operation margin is 3.05 V (Vp = −2.25 V). , Vq = −5.3V), and the white operating margin is 3.1V (Vp = −2.37V, Vq = −5.47V). The red operating margin is the narrowest, and the difference from the white operating margin is 1.54V.

  In order to show the improvement effect of the operation margin, the case where all the current driving capabilities of the driving TFTs 2 of the pixels A1 to A4 of the respective colors are set equal (referred to as Comparative Example 1) will be described. FIG. 7 is a diagram illustrating an IV characteristic curve of the driving TFT 2 of Comparative Example 1 and an IV characteristic curve of the organic EL element OEL. In Comparative Example 1, the driving TFT 2 of each color pixel A1 to A4 has a channel length L set to 50 μm and a channel width W set to 4 μm. The aperture area ratio of the pixels of each color is red: green: blue: white = 1: 1: 1: 1.

  In FIG. 7, a curve 76 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, and a curve 78 is an IV characteristic curve of the driving TFT 2 of the green and blue pixels A2 and A3. A curve 66 is an IV characteristic curve of the driving TFT 2 of the white pixel A4. Since the current driving capability of the driving TFT 2 is the same as the example shown in FIG. 6, the curve is the same IV characteristic curve as FIG. ing. A curve 60 is an IV characteristic curve of the organic EL element OEL. However, since the aperture area ratio of the pixel is the same as the example shown in FIG. 6, it is the same IV characteristic curve as FIG.

  The intersection of the curve 60 and the curve 76 is the operation point 82 of the red pixel A1, the intersection of the curve 60 and the curve 78 is the operation point 84 of the green and blue pixels A2 and A3, and the intersection of the curve 60 and the curve 66 is the white pixel A4. Operating point 86. Note that the saturation current Idss of each color driving TFT 2 is the same as that shown in FIG.

  As shown in FIG. 7, in the case of the comparative example 1, the operation margin of the red pixel A1 is 1.14V (Vp = −3.27V, Vq = −4.41V), and the green and blue pixels A2 and A3. The operation margin is 2.8V (Vp = −2.48V, Vq = −5.28V), and the operation margin of the white pixel A4 is 3.1V (Vp = −2.37V, Vq = −5.47V). It is. The operation margin of the red pixel A1 is the narrowest, and the difference from the operation margin of the white pixel A4 is 1.96V. Comparing the operation margin of each color shown in FIG. 6 with the operation margin of each color shown in FIG. 7, the difference between the operation margin of the white pixel A4 and the operation margins of the pixels A1 to A4 other than white is 1. The voltage is reduced from 96V to 1.54V.

  As described above, in the first embodiment, the current driving capability of the driving TFT 2 of the non-white pixels A1 to A3 is made larger than the current driving capability of the driving TFT 2 of the white pixel A4. The absolute value of the pinch-off voltage Vp of the driving TFT 2 of the pixels A1 to A3 is shifted in the direction of decreasing. That is, the operation margin is widened, and the difference in the operation margin between the white pixel A4 and the non-white pixels A1 to A3 is reduced. As a result, since the operation margin is narrow, it is not necessary to set the drive voltage (Vdd-CV) high, which is effective for reducing power consumption. Further, since the operation margin is widened, the organic EL element OEL can emit light with high accuracy and stability.

<Second Embodiment>
A second embodiment of the present invention will be described. The second embodiment is different from the first embodiment in that the aperture areas of red, green, blue, and white pixels are different from each other. The same components as those in the first embodiment will be described using the same symbols.

  It is known that the lifetime of the organic EL element OEL depends on the current density applied to the element. When the aperture area of each pixel is the same, in order to obtain a predetermined luminance in a pixel with poor light emission efficiency, it is necessary to pass a larger current than other pixels with good light emission efficiency. For this reason, in a pixel with low luminous efficiency, the life of the organic EL element OEL tends to be shortened.

  Since the frequency of use of each color when displaying an image differs depending on the color, by changing the aperture area according to the ratio of the average current supplied to the organic EL element OEL of each color pixel, The life can be smoothed and the life of the display device 10 can be extended.

  An example of the second embodiment is shown by setting specific numerical values. FIG. 8 is a diagram illustrating an IV characteristic curve of the driving TFT 2 and an IV characteristic curve of the organic EL element OEL according to the second embodiment. The aperture area ratio of each color pixel was set as red: green: blue: white = 5.3: 1.9: 1: 4.4. Also in the second embodiment, the channel length L of the driving TFT 2 is set so that the current driving capability of the driving TFT 2 in the pixels A1 to A3 other than white is larger than the current driving capability of the driving TFT 2 in the white pixel A4. Set the channel width W. Here, the driving TFT 2 of the pixels A1 to A3 other than white is set to have a channel length L = 40 μm and a channel width W = 6 μm, and the driving TFT 2 of the white pixel A4 has a channel length L = 50 μm and a channel width W = 4 μm. Was set.

  In FIG. 8, a curve 88 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 92 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 94 is the blue pixel A3. An IV characteristic curve, curve 90, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4. Since the aperture areas of the pixels of the respective colors are different, the IV characteristic curve of the organic EL element OEL becomes a different IV characteristic curve for each color.

  A curve 96 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, a curve 98 is an IV characteristic curve of the green and blue pixels A2 and A3, and a curve 100 is a driving of the white pixel A4. It is an IV characteristic curve of TFT2. The intersection point of the curve 88 and the curve 96 is the operating point 102 of the red pixel A1, the intersection point of the curve 92 and the curved line 98 is the operating point 106 of the green pixel A2, and the intersection point of the curved line 94 and the curve 98 is the operating point 108 of the blue pixel A3. The intersection of the curve 90 and the curve 100 is the operating point 104 of the white pixel A4.

  As shown in FIG. 8, the operating margin of the red pixel A1 is 2.64V (Vp = −2.48V, Vq = −5.12V), and the operating margin of the green pixel A2 is 2.59V (Vp = -1.96V, Vq = -4.55V), the operating margin of the blue pixel A3 is 1.64V (Vp = -1.96V, Vq = -3.6V), and the operating margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The blue pixel A3 operating margin is the narrowest, and the difference from the white operating margin is 1.9V.

  In order to show the improvement effect of the operation margin, a case where all the current driving capabilities of the driving TFTs 2 of the pixels A1 to A4 of the respective colors are set equal (referred to as Comparative Example 2) will be described. FIG. 9 is a diagram illustrating an IV characteristic curve of the driving TFT 2 of Comparative Example 2 and an IV characteristic curve of the organic EL element OEL. In Comparative Example 2, the driving TFT 2 of each color pixel A1 to A4 has a channel length L of 50 μm and a channel width W of 4 μm. The aperture area ratio of each color pixel is red: green: blue: white = 5.3: 1.9: 1: 4.4.

  In FIG. 9, a curve 88 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 92 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 94 is the blue pixel A3. An IV characteristic curve, curve 90, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4. Since the aperture area ratio of the pixel is the same as the example shown in FIG. 8, the same IV characteristic curve as that in FIG. 8 is obtained.

  A curve 118 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, and a curve 120 is an IV characteristic curve of the driving TFT 2 of the green and blue pixels A2 and A3. A curve 100 is an IV characteristic curve of the driving TFT 2 of the white pixel A4. Since the current driving capability of the driving TFT 2 is the same as the example shown in FIG. 8, the curve is the same IV characteristic curve as FIG. ing. The operating point 124 of the pixel A1 where the intersection of the curve 88 and the curve 118 is red, the operating point 128 of the pixel A2 where the intersection of the curve 92 and the curve 120 is green, and the operating point 130 of the pixel A3 where the intersection of the curve 94 and the curve 120 is blue. The intersection of the curve 90 and the curve 100 is the operating point 126 of the white pixel A4.

  As shown in FIG. 9, the operation margin of the red pixel A1 is 1.89V (Vp = −3.27V, Vq = −5.16V), and the operation margin of the green pixel A2 is 2.09V (Vp = −2.48V, Vq = −4.57V), the operation margin of the blue pixel A3 is 1.15V (Vp = −2.48V, Vq = −3.63V), and the operation margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The blue pixel A3 operating margin is the narrowest, and the difference from the white operating margin is 2.39V.

  Comparing the operation margin of each color shown in FIG. 8 with the operation margin of each color shown in FIG. 9, the difference between the operation margin of the white pixel A4 and the operation margins of the pixels A1 to A4 other than white is 2.39V. The voltage is reduced from 1.9V to 1.9V.

  As described above, also in the second embodiment, the current driving capability of the driving TFT 2 of the non-white pixels A1 to A3 is made larger than the current driving capability of the driving TFT 2 of the white pixel A4. The absolute value of the pinch-off voltage Vp of the driving TFT 2 of the pixels A1 to A3 is shifted in the direction of decreasing. That is, the operation margin is widened, and the difference in the operation margin between the white pixel A4 and the non-white pixels A1 to A3 is reduced. As a result, since the operation margin is narrow, it is not necessary to set the drive voltage (Vdd-CV) high, which is effective for reducing power consumption.

  Further, since the operation margin is widened, the organic EL element OEL can emit light with high accuracy and stability. In addition, since the opening area is changed for each color pixel, the lifetime of the organic EL element is smoothed, and the lifetime of the display device 10 can be extended.

<Third Embodiment>
A third embodiment of the present invention will be described. In the third embodiment, the current driving capability of the driving TFT 2 is set so that the absolute value of the pinch-off voltage of the pixels A1 to A3 other than white is smaller than the absolute value of the pinch-off voltage of the white pixel A4. Note that the same components as those in the first embodiment will be described using the same symbols.

  An example of the third embodiment will be described with specific numerical values set. FIG. 10 is a diagram illustrating an IV characteristic curve of the driving TFT 2 and an IV characteristic curve of the organic EL element OEL according to the third embodiment. The aperture area ratio of each color pixel was set to be red: green: blue: white = 5.3: 1.9: 1: 4.4, as in the second embodiment. Further, the driving TFT 2 of the pixels A1 to A3 other than white is set to have a channel length L = 35 μm and a channel width W = 7 μm, and the driving TFT 2 of the white pixel A4 has a channel length L = 50 μm and a channel width W = 4 μm. Set.

  In FIG. 10, a curve 88 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 92 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 94 is the blue pixel A3. An IV characteristic curve, curve 90, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4. Since the aperture area ratio of the pixel is the same as the example shown in FIGS. 8 and 9, it has the same IV characteristic curve as that in FIGS.

  A curve 138 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, and a curve 140 is an IV characteristic curve of the driving TFT 2 of the green and blue pixels A2 and A3. A curve 100 is an IV characteristic curve of the driving TFT 2 of the white pixel A4. Since the current driving capability of the driving TFT 2 is the same as the example shown in FIGS. 8 and 9, the same I as in FIGS. -V characteristic curve. The intersection point of the curve 88 and the curve 138 is the operating point 144 of the pixel A1, the intersection point of the curve 92 and the curve 140 is the operating point 148 of the green pixel A2, and the intersection point of the curve 94 and the curve 140 is the operating point 150 of the pixel A3 of blue. The intersection of the curve 90 and the curve 100 is the operating point 146 of the white pixel A4.

  As shown in FIG. 10, the operation margin of the red pixel A1 is 2.84V (Vp = −2.27V, Vq = −5.11V), and the operation margin of the green pixel A2 is 2.75V (Vp = −1.8V, Vq = −4.55V), the operation margin of the blue pixel A3 is 1.81V (Vp = −1.8V, Vq = −3.61V), and the operation margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The operation margin of the blue pixel A3 is the narrowest, and the difference from the operation margin of the white pixel A4 is 1.73V.

  Comparing the operation margin of each color shown in FIG. 10 with the operation margin of each color shown in FIG. 8, the difference between the operation margin of the white pixel A4 and the operation margin of the blue pixel A3 having the narrowest operation margin is 1 It is even smaller from .9V to 1.73V. Therefore, the third embodiment can reduce the power consumption more suitably than the second embodiment.

  Further, since the operation margin of the pixels A1 to A3 other than white is widened, the organic EL element OEL can emit light with high accuracy and stability. Also in the third embodiment, since the aperture area of the pixel is changed for each color, the life of the display device 10 can be extended as described in the second embodiment.

<Fourth embodiment>
A fourth embodiment of the present invention will be described. In the first to third embodiments, the current driving capabilities of the driving TFTs 2 of the pixels A1 to A3 other than white are all set equal, but in the fourth embodiment, the current driving capability of the driving TFT 2 for each color. Make them different. Note that the same components as those in the first embodiment will be described using the same symbols.

  As described above, when the current driving capability of the driving TFT 2 is increased by increasing the channel width W of the driving TFT 2 or by reducing the channel length L, the absolute value of the pinch-off voltage Vp decreases. Although the difference in margin can be reduced, if the channel width W is too large, the area of the driving TFT 2 is increased, and the aperture area of the pixel is decreased, which is not desirable. Further, when the channel length L is too small, the saturation current Idss becomes unstable in the IV characteristic curve of the driving TFT 2.

  Therefore, in the fourth embodiment, the channel width W of the driving TFT 2 is increased and the channel length L is set small in order to widen the operation margin for the pixel having the narrowest operation margin. As long as the operating margin does not fall below the narrowest color, the channel width W is reduced and the channel length L is set larger.

  An example of the fourth embodiment will be described with specific numerical values set. FIG. 11 is a diagram illustrating an IV characteristic curve of the driving TFT 2 and an IV characteristic curve of the organic EL element OEL according to the fourth embodiment. The aperture area ratio of each color pixel was set to be red: green: blue: white = 5.3: 1.9: 1: 4.4, as in the second and third embodiments. The driving TFT 2 of the red pixel A1 is set with a channel length L = 40 μm and the channel width W = 5 μm, and the driving TFT 2 of the green pixel A2 is set with a channel length L = 40 μm and a channel width W = 5 μm. The driving TFT 2 of the blue pixel A3 was set to have a channel length L = 25 μm and a channel width W = 10 μm, and the driving TFT 2 of the white pixel A4 was set to have a channel length L = 50 μm and a channel width W = 4 μm.

  In FIG. 11, a curve 88 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 92 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 94 is the blue pixel A3. An IV characteristic curve, curve 90, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4. Since the aperture area ratio of the pixel is the same as the example shown in FIGS. 8 to 10, it has the same IV characteristic curve as that of FIGS.

  A curve 160 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, a curve 162 is an IV characteristic curve of the driving TFT 2 of the green pixel A2, and a curve 164 is an I-V of the driving TFT 2 of the blue pixel A3. It is a V characteristic curve. A curve 100 is an IV characteristic curve of the driving TFT 2 of the white pixel A4. Since the current driving capability of the driving TFT 2 is the same as the example shown in FIGS. 8 to 10, the same I as that in FIGS. -V characteristic curve. The operating point 168 of the pixel A1 where the intersection of the curve 88 and the curve 160 is red, the operating point 172 of the pixel A2 where the intersection of the curve 92 and the curve 162 is green, and the operating point 174 of the pixel A3 where the intersection of the curve 94 and the curve 164 is blue The intersection of the curve 90 and the curve 100 is the operating point 170 of the white pixel A4.

  As shown in FIG. 11, the operation margin of the red pixel A1 is 2.4V (Vp = −2.72V, Vq = −5.12V), and the operation margin of the green pixel A2 is 2.45V (Vp = −2.11V, Vq = −4.56V), the operation margin of the blue pixel A3 is 2.27V (Vp = −1.4V, Vq = −3.67V), and the operation margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The operation margin of the blue pixel A3 is the narrowest, and the difference from the operation margin of the white pixel A4 is 1.27V.

  Comparing the operation margin of each color shown in FIG. 11 with the operation margin of each color shown in FIG. 10, the difference between the operation margin of the white pixel A4 and the operation margin of the blue pixel A3 having the narrowest operation margin is 1 It is even smaller from .73V to 1.27V. The operation margin of the red and green pixels A1 and A2 is smaller than that of the third embodiment because the current driving capability of the driving TFT 2 is reduced. Since the operation margin can be secured, the operation margin of the display device 10 as a whole is improved. Therefore, also in the fourth embodiment, power consumption can be reduced.

  In addition, by making the current driving capability of the driving TFT 2 different for each color, it is possible to increase the opening area for a color pixel that does not require a large operation margin, and to stabilize the saturation current of the driving TFT 2. Can be made.

<Fifth embodiment>
A fifth embodiment of the present invention will be described. In the fifth embodiment, the aperture area ratio of each color pixel is different from the second to fourth embodiments, and the aperture area of the white pixel A4 is larger than the aperture areas of the non-white pixels A1 to A3. Set to be larger. This is because white pixels are used most frequently when a plurality of arbitrary natural images such as landscape photographs and portrait photographs are displayed. By setting the aperture area of the white pixel having the highest use frequency larger than that of the other color pixels, the current flowing through the white pixel can be reduced, and the lifetime of the white pixel can be extended.

  An example of the fifth embodiment is shown by setting specific numerical values. FIG. 12 is a diagram illustrating an IV characteristic curve of the driving TFT 2 and an IV characteristic curve of the organic EL element OEL according to the fifth embodiment. The aperture area ratio of the pixels of each color was set to be red: green: blue: white = 2.7: 1.7: 1: 2.9 so that the aperture area of the white pixel A4 was the largest. Further, the driving TFT 2 of the pixels A1 to A3 other than white is set to have a channel length L = 35 μm and a channel width W = 7 μm, and the driving TFT 2 of the white pixel A4 has a channel length L = 50 μm and a channel width W = 4 μm. Set.

  In FIG. 12, a curve 178 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 180 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 182 is the blue pixel A3. An IV characteristic curve, curve 176, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4.

A curve 184 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, a curve 186 is an IV characteristic curve of the driving TFT 2 of the green and blue pixels A3, and a curve 188 is a driving of the white pixel A4. It is an IV characteristic curve of TFT2. The intersection point of the curve 178 and the curve 184 is the operating point 190 of the red pixel A1, the intersection point of the curve 180 and the curve 186 is the operating point 194 of the green pixel A2, and the intersection point of the curve 182 and the curve 186 is the operating point 196 of the blue pixel A3. The intersection of the curve 176 and the curve 188 is the operating point 192 of the white pixel A4.

  As shown in FIG. 12, the operation margin of the red pixel A1 is 2.47V (Vp = −2.27V, Vq = −4.74V), and the operation margin of the green pixel A2 is 3.18V (Vp = −1.8V, Vq = −4.98V), the operation margin of the blue pixel A3 is 2.43V (Vp = −1.8V, Vq = −4.23V), and the operation margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The operation margin of the blue pixel A3 is the narrowest, and the difference from the operation margin of the white pixel A4 is 1.11V.

  In order to show the improvement effect of the operation margin, the case where all the current driving capabilities of the driving TFTs 2 of the pixels A1 to A4 of the respective colors are set equal (referred to as Comparative Example 3) will be described. FIG. 13 is a diagram illustrating an IV characteristic curve of the driving TFT 2 of Comparative Example 3 and an IV characteristic curve of the organic EL element OEL. In Comparative Example 3, the drive TFT 2 of each color pixel A1 to A4 has a channel length L set to 50 μm and a channel width W set to 4 μm. The aperture area ratio of each color pixel is red: green: blue: white = 2.7: 1.7: 1: 2.9.

  In FIG. 13, a curve 178 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 180 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 182 is the blue pixel A3. An IV characteristic curve, curve 176, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4. Since the aperture area ratio of the pixel is the same as the example shown in FIG. 12, it has the same IV characteristic curve as FIG.

  A curve 206 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, and a curve 208 is an IV characteristic curve of the driving TFT 2 of the green and blue pixels A2 and A3. A curve 188 is an IV characteristic curve of the driving TFT 2 of the white pixel A4. However, since the current driving capability of the driving TFT 2 is the same as the example shown in FIG. 12, it is the same IV characteristic curve as FIG. ing. The intersection point of the curve 178 and the curve 206 is the operating point 212 of the red pixel A1, the intersection point of the curve 180 and the curved line 208 is the operating point 216 of the green pixel A2, and the intersection point of the curved line 182 and the curved line 208 is the operating point 218 of the pixel A3. The intersection of the curve 176 and the curve 188 is the operating point 214 of the white pixel A4.

  As shown in FIG. 13, the operation margin of the red pixel A1 is 1.53V (Vp = −3.27V, Vq = −4.8V), and the operation margin of the green pixel A2 is 2.53V (Vp = Vp = V). −2.48V, Vq = −5.01V), the operation margin of the blue pixel A3 is 1.77V (Vp = −2.48V, Vq = −4.25V), and the operation margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The operation margin of the red pixel A3 is the narrowest, and the difference from the operation margin of the white pixel A4 is 2.01V.

  When the operation margin of each color shown in FIG. 12 is compared with the operation margin of each color shown in FIG. 13, the difference between the operation margin of the white pixel A4 and the narrowest operation margin among the pixels A1 to A3 other than white is as follows. The voltage is reduced from 2.01V to 1.11V.

  As described above, also in the fifth embodiment, by setting the current driving capability of the driving TFT 2 of the pixels A1 to A3 other than white to be larger than the current driving capability of the driving TFT 2 of the white pixel A4, the operation margin is increased. As a result, the difference in operation margin between the white pixel A4 and the non-white pixels A1 to A3 is reduced. As a result, since the operation margin is narrow, it is not necessary to set the drive voltage (Vdd-CV) high, which is effective for reducing power consumption.

  Further, since the operation margin is widened, the organic EL element OEL can emit light with high accuracy and stability. In addition, since the aperture area of the white pixel that is most frequently used is set larger than that of the other color pixels, the current flowing through the white pixel can be reduced, and the lifetime of the white pixel can be extended. it can. That is, the lifetime of the pixel is smoothed, and the lifetime of the display device 10 can be extended.

<Sixth Embodiment>
A sixth embodiment of the present invention will be described. In the fifth embodiment, the current driving capability of the driving TFT 2 of the non-white pixels A1 to A3 is set in a state where the opening area of the white pixel A4 is set larger than the opening areas of the non-white pixels A1 to A3. Although all are set equal, in the sixth embodiment, the current driving capability of the driving TFT 2 is set differently for each color.

  An example of the sixth embodiment will be described with specific numerical values set. FIG. 14 is a diagram illustrating an IV characteristic curve of the driving TFT 2 and an IV characteristic curve of the organic EL element OEL according to the sixth embodiment. The aperture area ratio of each color pixel was set to be red: green: blue: white = 2.7: 1.7: 1: 2.9, as in the fifth embodiment. Further, the driving TFT2 of the red and blue pixels A1 and A3 is set to have a channel length L = 30 μm and a channel width W = 8 μm, and the driving TFT2 of the green pixel A2 is set to have a channel length L = 35 μm and a channel width W = 7 μm. The driving TFT 2 of the white pixel A4 was set to have a channel length L = 50 μm and a channel width W = 4 μm.

  In FIG. 14, a curve 178 is an IV characteristic curve of the organic EL element OEL of the red pixel A1, a curve 180 is an IV characteristic curve of the organic EL element OEL of the green pixel A2, and a curve 182 is the blue pixel A3. An IV characteristic curve, curve 176, of the organic EL element OEL is an IV characteristic curve of the organic EL element OEL of the white pixel A4. Since the aperture area ratio of the pixel is the same as the example shown in FIGS. 12 and 13, the same IV characteristic curve as that in FIGS.

A curve 178 is an IV characteristic curve of the driving TFT 2 of the red pixel A1, a curve 230 is an IV characteristic curve of the driving TFT 2 of the green pixel A2, and a curve 232 is an IV of the driving TFT 2 of the blue pixel A3. It is a V characteristic curve. A curve 188 is an IV characteristic curve of the driving TFT 2 of the white pixel A4. Since the current driving capability of the driving TFT 2 is the same as the example shown in FIGS. 12 and 13, the same I as in FIGS. -V characteristic curve. The intersection point of the curve 178 and the curve 178 is the operating point 236 of the red pixel A1, the intersection point of the curve 180 and the curved line 230 is the operating point 240 of the green pixel A2, and the intersection point of the curved line 182 and the curve 232 is the operating point 242 of the blue pixel A3. The intersection of the curve 176 and the curve 188 is the operating point 238 of the white pixel A4.

  As shown in FIG. 14, the operation margin of the red pixel A1 is 2.82V (Vp = -1.97V, Vq = -4.79V), and the operation margin of the green pixel A2 is 3.18V (Vp = −1.8V, Vq = −4.98V), the operation margin of the blue pixel A3 is 2.73V (Vp = −1.57V, Vq = −4.3V), and the operation margin of the white pixel A4 is 3.54V (Vp = -2.37V, Vq = -5.91V). The operation margin of the blue pixel A3 is the narrowest, and the difference from the operation margin of the white pixel A4 is 0.81V.

  Comparing the operation margin of each color shown in FIG. 14 with the operation margin of each color shown in FIG. 13, the difference between the operation margin of the white pixel A4 and the operation margin of the blue pixel A3 having the narrowest operation margin is 1 It is even smaller from .11V to 0.81V. Therefore, in the sixth embodiment, the power consumption of the display device 10 can be more preferably reduced by reducing the difference between the operation margins of the pixels of the respective colors.

  Further, in the example shown in FIG. 12, for the green pixel A2, which has ensured a wide operation margin as compared with the red and blue pixels A1 and A3, the size of the driving TFT 2 is not changed. It is possible to prevent the area from being reduced.

  In the first to sixth embodiments described above, the display device including white pixels has been described. However, the present invention can be applied to any display device including pixels of a plurality of display colors. . When the light emission efficiency of each color changes depending on the light emission characteristics of the organic EL element and the transmission characteristics of the color filter, the color with the smallest operation margin may be different. Even in this case, the power consumption can be reduced by setting the current driving capability of the driving TFT 2 so that the difference between the operation margins of the pixels of the respective colors becomes small.

  The present invention has been described based on the embodiments. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to combinations of the respective constituent elements and processing processes, and such modifications are also within the scope of the present invention. is there.

FIG. 1A is a diagram showing a drive circuit of an organic EL element OEL using a TFT, and FIG. 1B is an IV characteristic curve of the TFT and an IV characteristic curve of the organic EL element OEL. FIG. It is a figure which shows the pixel layout of the display apparatus which concerns on 1st Embodiment. FIG. 3 is an equivalent circuit diagram of one pixel A1, A2, A3, and A4 in the display device shown in FIG. It is a figure which shows typically the cross section of the display apparatus which concerns on 1st Embodiment. FIG. 5A is a plan view schematically illustrating the structure of the driving TFT, and FIG. 5B is a diagram schematically illustrating the structure of the driving TFT 2. It is a figure which shows the IV characteristic curve of the drive TFT which concerns on 1st Embodiment, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT of the comparative example 1, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT which concerns on 2nd Embodiment, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT of the comparative example 2, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT which concerns on 3rd Embodiment, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT which concerns on 4th Embodiment, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT which concerns on 5th Embodiment, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT of the comparative example 3, and the IV characteristic curve of the organic EL element OEL. It is a figure which shows the IV characteristic curve of the drive TFT which concerns on 6th Embodiment, and the IV characteristic curve of the organic EL element OEL.

Explanation of symbols

  1 switching TFT, 2 driving TFT, 10 display device, 16 color filter, 17 organic EL light emitting layer, A1, A2, A3, A4 pixels, DL data line, OEL organic EL element, PVDD power supply line, SC storage capacitor, SL Gate line.

Claims (5)

A display device comprising pixels each including a self-luminous element that emits light upon receiving a current supply and a thin film transistor that controls a supply current to the self-luminous element,
It has pixels of multiple display colors including white,
A current supply amount to the self-light-emitting element necessary for displaying the pixel with a desired luminance is the smallest among white pixels among the plurality of display color pixels.
The current driving capability of the thin film transistor in the white pixel is smaller than the current driving capability of the thin film transistor in any display color pixel other than white,
The area of the light emitting element that emits light in the pixels of each color is a plurality of display color pixels.
Maximum for white pixels,
The current driving capability of the thin film transistor of each color is set so that the absolute value of the pinch off voltage of the thin film transistor in a pixel other than white is smaller than the absolute value of the pinch off voltage of the thin film transistor in a white pixel. Display device. The display device according to claim 1, wherein a current driving capability of the thin film transistor is different for each color. The display device according to claim 1 , wherein the plurality of display colors are four colors of red, green, blue, and white. 4. The display device according to claim 1, wherein a color emitted from the self-luminous element is white, and other display colors are converted using a color filter. 5. The display device according to claim 1 , wherein the self-luminous element is an organic electroluminescence element.

Images