JP4428535B2 - Display device driver - Google Patents

Description

  The present invention relates to a display device driver and a display device for driving a display device such as a liquid crystal panel, and more particularly to a circuit device for supplying a uniform current to the display device driver.

  In recent years, flat panel displays (FPDs) have become large screens and high definition, and are becoming thinner and lighter and lower in cost. In such a background, improvement of a display device driver LSI for driving a display panel such as an FPD is underway.

  FIG. 7A is a diagram schematically showing a configuration of a display panel portion of a liquid crystal display device, FIG. 7B is a circuit diagram showing a configuration of a conventional display device driver, and FIG. It is a figure which shows the dispersion | variation in the brightness | luminance of a display panel. Note that here, an example of a liquid crystal display panel in which gradation control is performed by voltage level is shown.

  As shown in FIGS. 7A and 7B, a general TFT (Thin-Film-Transistor) driving type liquid crystal display panel includes a transparent TFT 602 and a liquid crystal capacitor 603 connected to the TFT 602. Pixels (subpixels) 601 are arranged in a matrix. Each pixel 601 is connected to each drive voltage supply unit in the display device driver LSI 605, and is supplied with a voltage for gradation control from the display device driver LSI 605. In the display device driver LSI 605, in addition to the bias current circuit 606, a plurality of drive voltage supply units such as a drive voltage supply unit 619, a drive voltage supply unit 620, and a drive voltage supply unit 621 are integrated on one chip. It has been In the case of a large-screen liquid crystal display device, a plurality of such display device driver LSIs 605 are arranged on the frame portion of the display panel. In this specification, a circuit including a bias current circuit (current source) and a drive voltage supply unit is referred to as a “display device driver”.

  In this display panel, by changing the voltage value applied to the liquid crystal capacitor 603, the level at which the display pixel shields the backlight light changes. As a result, a change in display luminance proportional to the voltage applied from the display device driver can be obtained.

  Next, the configuration of a conventional display device driver LSI shown in FIG. 7B will be described.

  First, the bias current circuit 606 for supplying a constant current to the drive voltage supply unit 619 includes a first conductivity type first MOSFET 608, a resistor 607 connected to the first MOSFET 608, and a first MOSFET 608. And a second MOSFET 609 constituting a current mirror, and a second conductivity type input transistor 610 connected to the second MOSFET 609. The input transistor 610 is for inputting a current to a current mirror section in a drive voltage supply section 619 described later.

  Next, the drive voltage supply unit 619 includes a current addition type D / A converter 630 having a plurality of current mirrors, and a current / voltage converter 611 connected to the output unit of the D / A converter 630. .

The D / A converter 630 is configured by a second conductivity type (here, N-channel type) MOSFET, and includes a first current mirror CM ₁ , a second current mirror CM ₂ , and a current mirror that form an input transistor 610, ... a current mirror CM _n of the n, the first current mirror CM _1, the second current mirror CM _2, ... switch L _1, L ₂ connected to each of the current mirror CM _n of the n, ... and Ln (N is a natural number). The current / voltage converter includes an operational amplifier and a resistor that are negatively fed back. The drive voltage supply units 620 and 621 also have the same configuration as the drive voltage supply unit 619, and the gate electrodes of the current mirrors of the plurality of drive voltage supply units are connected in common.

  Next, the current flowing through the conventional display device driver will be described.

Among the conventional display device drivers, the bias current circuit 606 can adjust the resistance value of the resistor 607 to generate a reference current having a desired magnitude. The reference current is distributed to the second MOSFET 609 and input to the input transistor 610. Then, the first current mirror CM _1, the second current mirror CM _2, ... current flows to each of the current mirror CM _n of the n. Here, in FIG. 7B, each current mirror is simply shown as being composed of one transistor, but in reality, one, two, four,..., 2 ^n−1. The transistors are equal in size. For example, in the case of a 6-bit (64 gradation) liquid crystal display device, 1 + 2 + 4 + 8 + 16 + 32 = 63 transistors are arranged in accordance with the weight of the bit. Therefore, when the current flowing when switch L ₁ is on the I, switch L _2, L ₃ ..., the current flowing through the respective switch when the L _n is turned on, 2I, 4I, ..., 2 ^{n- 1} I. Therefore, 2 ⁿ current levels can be input to the current / voltage converter 611 by controlling on or off of the switches L ₁ , L ₂ ..., L _n . The current / voltage converter 611 converts the input current into a voltage and supplies the voltage to the pixel 601.

  Next, the operation of a conventional display device driver will be briefly described.

In a conventional display device driver, display data is held as a digital signal (not shown). The switches L ₁ , L ₂ ,..., L _n are turned on or off in accordance with the display data. In the case of all white display, all the switches from the switch L ₁ to the switch L _n are turned on. On the other hand, in the case of all black display, all the switches from the switch L ₁ to the switch L _n are turned off.
JP 2001-147659 A JP 2001-67048 A JP 2001-166867 A

  According to the above-described conventional display device driver, it is possible to drive a small-screen display panel such as a mobile phone display panel without any trouble.

  However, as the display panel has been enlarged, the length of the driver LSI for the display device (length in the long side direction) has reached 10 mm to 20 mm. In such a case, in the conventional display device driver LSI, the output voltage varies between the output terminals separated from each other, and there is a possibility that the image quality is deteriorated, such as a bright and dark part in the display image.

  When the inventor of the present application investigated the cause of the variation in output voltage between the output terminals of the display device driver LSI, it was found that the current distributed to each current mirror of the display device driver had variations. In the first place, the current mirror circuit is based on the premise that the diffusion conditions of the transistors constituting the current mirror circuit are equal, and that there is no significant difference in threshold value Vt and carrier mobility. In addition, the current is distributed according to the size ratio of the transistors. However, when the length of the chip of the driver LSI for display device is as long as 10 mm to 20 mm, it is considered difficult to uniformly diffuse the impurities contained in the transistor. As a result, the threshold value of the transistor serving as the current mirror varies, and as a result, the output voltage varies. Usually, the variation in diffusion has a gradual inclination with respect to the wafer surface. For this reason, even when uniform display with constant display data is performed, as shown in FIG. 7C, a gradation from light to dark occurs on the display panel.

  An object of the present invention is to provide means for suppressing variations between outputs of driver LSIs for display devices.

A display device driver according to the present invention includes a first conductivity type first reference current transistor for driving a reference current flowing in a first node and a first current for driving a reference current flowing in a second node. A second conductivity type first current transistor having a conductivity type second reference current transistor and a drain electrically connected to the first node, wherein the gate electrode and the drain are electrically connected to each other. The input transistor has a drain electrically connected to the second node , the gate electrode and the drain are electrically connected to each other, and the gate electrode is electrically connected to the gate electrode of the first current input transistor. each disposed in an area sandwiched between the connection and the second current input Chikarato transistor of the second conductivity type which is the first current input Chikarato transistor and said second current input Chikarato transistor to , A plurality of current mirror transistor having a gate electrode is electrically connected to the gate electrode of the first current input transistor and said second current input transistor of people, depending on the current flowing through the plurality of current mirror transistor And a drive circuit for driving the display element .

  With this configuration, current is distributed from at least two reference current sources to a plurality of current mirrors, so that variations in threshold values (or current driving power) of transistors constituting the current mirror are offset by impurity diffusion variations and the like. be able to. Therefore, since the output current from the current mirror can be made uniform, it is possible to suppress variations in luminance even in a large-screen current-driven display device. Further, by adding a current / voltage conversion circuit, a large-screen liquid crystal display device with improved display quality can be realized.

  Further, the plurality of current mirrors are arranged between the first current input transistor and the second current input transistor, so that the first current input transistor control unit and the second current mirror are connected to each other. Since a potential gradient can be generated between the current input transistor and the control unit of the current input transistor, variations in threshold values of the transistors constituting the current mirror can be more effectively offset. As a result, the variation in current generated in the current mirror can be further suppressed, so that the display quality of the display device can be further improved.

A first conductive type first electrode having a gate electrode electrically connected to a gate electrode of each of the first reference current transistor and the second reference current transistor, wherein the drain and the gate electrode are electrically connected to each other; 1 transistor, the first reference current transistor and the second reference current transistor have the same W / L ratio, and constitute a current mirror circuit with the first transistor. The first and second reference current transistors that supply the same current to each other using the circuit can be realized with a simple configuration.

Wherein the first reference current transistor and the second reference current transistor, is arranged near to the mutual distance is 100 micrometers or less, wherein the first reference current transistor first current input Chikarato the length and width of the wiring connecting the transistor, by the is substantially identical to the length and width of the wiring and the second reference current transistor connecting the second current input Chikarato transistor, first the current flowing through the current input Chikarato transistor and the error between the current flowing through the second current input Chikarato transistor can be minimized.

Among the plurality of current mirror transistor, between the gate electrode of the first current input transistor and the gate electrode of the current mirror transistors adjacent to the first current input Chikarato transistor, among the plurality of current mirror transistor , between the gate electrodes of the current mirror transistors adjacent to each other, and among the plurality of current mirror transistors, said gate electrode of the current mirror transistors adjacent to the second current input Chikarato transistor second current input Chikarato transistor between the gate electrode of, by Ru provided with resistive elements each having a same resistance value, sufficiently between the first current input Chikarato transistor gate electrode of the gate electrode and the second current input Chikarato transistor of Even if a strong potential gradient cannot be formed, the voltage drop due to the resistance element is used. It is possible to have a place gradient. As a result, it is possible to further suppress variations in current that occur in a plurality of current mirrors.

  A fourth reference current source that forms a current mirror with the first transistor, and that includes a transistor having a size ratio equal to that of the first reference current source and the second reference current source; and the fourth reference current source A current transmission terminal connected to the first transistor is further provided on the same chip as the first transistor, and a resistor connected to the first transistor is provided on the same chip as the first transistor. Thus, it can be used as a first stage display device driver when a plurality of display device drivers are connected. That is, since the reference current generated by the fourth reference current source can be transmitted to the display device driver at the next stage via the current transmission terminal, even if the characteristics of the current mirror vary between chips, the current The output current of the mirror can be made uniform.

  A first current input / output terminal for transmitting a reference current; a second diffusion layer; a first diffusion layer connected to the first current input / output terminal; and a control unit. A current mirror circuit is formed with the second transistor having a conductive second transistor, a second diffusion layer and a control unit, and a first diffusion layer connected to the first diffusion layer of the first transistor. The third transistor of the first conductivity type is further provided on the same chip as the first transistor, so that when a plurality of display device drivers are connected, the second and subsequent display devices It can be used as a driver.

  A fourth transistor of the first conductivity type cascode-connected to the second diffusion layer of the second transistor, and a cascode-connected to the second diffusion layer of the third transistor, the fourth transistor and the current mirror circuit When the plurality of display device drivers are connected, the fifth transistor of the first conductivity type constituting the first transistor is further provided on the same chip as the first transistor. It can be used as a driver for a display device. In addition, the fluctuation of the reference current transmitted from the display device driver in the previous stage can be minimized by the current mirror composed of the cascode-connected transistors.

  A second current input / output terminal connected to the first diffusion layer of the first transistor and the first diffusion layer of the third transistor; and a current mirror with the first transistor; and A fourth reference current source composed of transistors having the same size ratio as the first reference current source and the second reference current source, and a current transmission terminal connected to the fourth reference current source. Further, a common reference current can be distributed to a plurality of display device drivers by cascading only one type of chip. Therefore, if this display device driver is used, a display panel with improved display quality can be provided at a lower cost.

  The first reference current source, the second reference current source, the first current input transistor, the second current input transistor, and the plurality of current mirrors have a first diffusion layer as a drain, a second current mirror, A MOSFET having a diffusion layer as a source and a control unit as a gate electrode may be used.

  The display device driver according to the present invention includes a plurality of reference current sources, a plurality of current input MOSFETs respectively connected to the plurality of reference current sources, and a plurality of current input MOSFETs. A plurality of current mirrors for distributing the current input to the MOSFET, and a current adding means for changing the output current value by adding the currents generated by the plurality of current mirrors. As a result, currents of equal magnitude can be input from both ends of the plurality of current mirrors, so that variations in current flowing through each of the plurality of current mirrors can be suppressed. Accordingly, it is possible to drive a current-driven or voltage-driven display panel without variation in luminance.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a circuit diagram showing a display device driver according to the first embodiment of the present invention, and FIG. 2 shows a drive voltage supply unit for 64 gradations in the display device driver of this embodiment. It is a circuit diagram. The display device driver of this embodiment is preferably used for driving a voltage-driven display device such as a liquid crystal display device.

As shown in FIG. 1, the display device driver of the present embodiment is characterized in that at least two current sources for generating a reference current I ₁ are provided using a current mirror circuit. Hereinafter, the configuration of the display device driver will be described in detail.

  As shown in FIGS. 1 and 2, the display device driver of this embodiment includes a bias current circuit for supplying a constant value of current to the drive voltage supply unit.

  The bias current circuit includes a first conductivity type first MOSFET 18, a resistor 17 connected to the first MOSFET 18, a second MOSFET 19 and a third MOSFET 21 that form a current mirror with the first MOSFET 18, A first current input MOSFET 10 of the second conductivity type connected to the second MOSFET 19 and a second current input MOSFET 12 of the second conductivity type connected to the third MOSFET 21 are provided. . The gate electrode of the first current input MOSFET 10 and the gate electrode of the second current input MOSFET 12 are electrically connected. The resistor 17 described above may be provided inside the chip or may be provided outside.

  1 and 2 show an example in which the first conductivity type is an N-channel type and the second conductivity type is a P-channel type, but the first conductivity type is a P-channel. The type and the second conductivity type may be an N channel type. This is common throughout the following embodiments.

Although not shown in FIG. 1, the first current input MOSFET 10 and the second current input MOSFET 12 are connected to the current between the first current input MOSFET 10 and the second current input MOSFET 12. A current mirror group 9 constituting a mirror is provided. Here, the current mirror group 9 is a part of the drive voltage supply unit, and each of the first current mirror CM ₁ , the second current mirror CM ₂ ,. It consists of a current mirror CM _n . In addition, the second MOSFET 19 and the third MOSFET 21 are preferably arranged in the vicinity of each other in order to suppress variation in characteristics. The distance between the second MOSFET 19 and the third MOSFET 21 is usually preferably 10 μm or more and 100 μm or less.

On the other hand, as shown in FIG. 2, the drive voltage supply unit has the same configuration as the conventional one, and the current is constituted by the current mirror group 9 and the switches L _{1 to} L _n (current adding means) connected to each current mirror. It has an addition type D / A converter, and a current / voltage converter 20 connected to the output part of the D / A converter and comprising an operational amplifier and a resistor. Here, in FIG. 1, each of the first current mirror CM ₁ , the second current mirror CM ₂ ,..., And the n-th current mirror CM _n is shown in a simplified manner so as to be configured by one MOSFET. However, it is actually composed of MOSFETs having the same size ratio (W / L ratio) in which one, two, four,..., 2 ^n-1 gates are connected in common.

  In FIG. 2, only the current mirror in one drive voltage supply unit arranged between the first current input MOSFET 10 and the second current input MOSFET 12 is shown. Are sandwiched between current mirrors in a plurality of drive voltage supply units.

  Next, the current flowing through the display device driver of this embodiment including a current source will be described.

First, in the bias current circuit, a current of a predetermined value flows through the first MOSFET 18 by providing the resistor 17. Then, this current is distributed to the second MOSFET 19 and the third MOSFET 21, and the reference currents I ₁ having substantially the same magnitude flow at the same time.

Next, the reference current I ₁ is input to the drains of the first current input MOSFET 10 and the second current input MOSFET. Then, when the switches L ₁ , L ₂ ,... L _n are in the on state, the current I ₂ flows through each of the MOSFETs constituting the current mirror group 9. That is, the switch L _1, L ₂ in the ON state in the example shown in FIG. 2, ... in L _n, respectively _{I 2, 2I 2, ... 2} n-1 I 2 of current flows. Therefore, 2 ⁿ current levels can be input to the current / voltage converter 20 by controlling the on / off of the switches L ₁ , L ₂ ..., L _n . In other words, the switches L _{1 to} L _n function as current adding means for changing the output current value by adding the current generated by the current mirror.

  Then, the current / voltage converter 20 converts the input current into a voltage and supplies it to, for example, a pixel of the liquid crystal display device.

In the display device driver of this embodiment, the reference current I ₁ is, for example, 630 nA, the current I ₂ is 10 nA, and I ₁ : I ₂ = 63: 1. The reason why the reference current I ₁ is made larger than the current I ₂ is to reduce the resistance value when the resistor 17 is provided outside the chip. The resistance value of the resistor 17 is, for example, about 1 MΩ. However, if the resistance value is too large, it is not preferable because it is easily affected by the external environment. Further, if the size ratios of the first MOSFET 18 and the second MOSFET 19 and the third MOSFET 21 are different, the value of the current generated in the first MOSFET 18 and the value of the reference current I ₁ are different.

In the display device driver of this embodiment, display data is held as a digital signal (not shown). The switches L ₁ , L ₂ ,..., L _n are turned on or off in accordance with the display data. In the case of all white display, all the switches from the switch L ₁ to the switch L _n are turned on. On the other hand, in the case of all black display, all the switches from the switch L ₁ to the switch L _n are turned off.

  Also in the display device driver of the present embodiment, the first current input MOSFET 10, the current mirror group 9, and the second current input MOSFET 12 are arranged in the length direction of the display device driver LSI according to the arrangement of the output terminals. Therefore, these threshold values Vt vary depending on the diffusion conditions at the time of LSI formation.

However, according to the display device driver of the present embodiment, currents of equal magnitude are input not only from the first current mirror CM ₁ side but also from the nth current mirror CM _n side. Compared with the device driver, the variation in current generated in each MOSFET constituting the current mirror group 9 can be suppressed to be small.

  The reason is as follows.

In general, in one semiconductor chip, the degree of diffusion of impurities varies with an inclination from one end to the other end. Thus, for example, as the from the first current mirror CM ₁ toward the current mirror CM _n of the n, MOSFET threshold that constitutes the current mirror is increased (or decreased). If the gate voltages Vgs of the MOSFETs constituting the current mirror group 9 are the same in this state, the current flowing through the MOSFET having a high threshold value becomes relatively small, and the current value flowing through the current mirror varies. For this reason, in the conventional display device driver, the current generated in the current mirror arranged in the LSI changes and deviates from the theoretical value.

On the other hand, the display device driver according to the present embodiment is configured to supply the same current from both ends of the current mirror group 9 considered to have the largest variation in threshold value. For example, when the threshold value of the second current input MOSFET 12 is higher than the threshold value of the first current input MOSFET 10, the second current input MOSFET 12 includes a current flowing through the first current input MOSFET 10. Since substantially equal current flows, the gate voltage Vgs applied to the second current input MOSFET 12 is higher than the gate voltage Vgs applied to the first current input MOSFET 10. Therefore, Vgs applied to the gate electrodes of the first current input MOSFET 10, the first current mirror CM ₁ , the second current mirror CM ₂ , and the nth current mirror CM _n has an inclination inside the LSI. become. As a result, the gradient of Vgs and the variation in threshold value are canceled out, so that a more uniform current can be generated by the current mirror inside the driver LSI for display device.

  Thus, since the current generated in each current mirror in the current mirror group 9 can be made substantially uniform, the output current of each D / A converter can also be made substantially uniform. Therefore, variations in the output voltage from the drive voltage supply unit in the same LSI can be suppressed. Therefore, if the display device driver of the present embodiment is used, it is possible to effectively suppress variations in luminance of the display panel.

  In particular, the display device driver of the present embodiment is effective when the length of the LSI chip in the long side direction exceeds 10 mm. Therefore, the display device driver of the present embodiment can be preferably used for a large-screen or high-definition liquid crystal display device.

  In the display device driver of the present embodiment, as described above, it is preferable that the second MOSFET 19 and the third MOSFET 21 functioning as current sources be arranged in the vicinity in order to distribute equal currents to each other. Further, it is preferable that the second MOSFET 19 and the third MOSFET 21 are arranged near the center of the display device driver LSI with the least variation in impurity diffusion. Further, in order to supply the same reference current to the first current input MOSFET 10 and the second current input MOSFET 12, a wiring for connecting the second MOSFET 19 and the first current input MOSFET 10 and a third MOSFET 21 are provided. And the wiring connecting the second current input MOSFET 12 are preferably equal in length and width. In addition to this, the first MOSFET 18 is also preferably in the vicinity of the second MOSFET 19 and the third MOSFET 21.

Further, between the second MOSFET 19 and the third MOSFET 21, MOSFETs that constitute both transistors and a current mirror can be further provided to serve as the third current source of the current mirror group 9. In this case, a current input MOSFET that receives the reference current I ₁ from the third current source is arranged at the center of the current mirror group 9. Thereby, the current generated in the current mirror of the drive voltage supply unit can be made more uniform.

The first current input MOSFET 10 and the second current input MOSFET 12 shown in FIGS. 1 and 2 are each shown as one MOSFET, but instead of this, a reference current I ₁ is used. On the other hand, a current mirror circuit composed of a plurality of MOSFETs connected in parallel may be used. Since the reference current I ₁ is often set to a value larger than that of each current mirror I ₂ , in this case, a plurality of small-sized MOSFETs are used rather than a single large-sized MOSFET. This is preferable because accuracy is improved.

  In the above description, an example in which a current mirror circuit having a plurality of reference current sources is used for a voltage-driven display device driver has been shown. It is also possible to drive the display device. In that case, the current / voltage converter 20 may be removed from the drive voltage supply unit shown in FIG.

  Note that the display device driver according to the present embodiment can be operated by using a bipolar transistor instead of the MOSFET constituting the current mirror.

  Further, the display device driver of the present embodiment can be used for a printer head in addition to the display device.

(Second Embodiment)
FIG. 3 is a circuit diagram showing a display device driver according to the second embodiment of the present invention.

  As shown in the figure, the display device driver of the present embodiment is characterized by having resistors having the same resistance value between the current input MOSFETs adjacent to each other and the gate electrodes of the current mirror and between the gate electrodes of the current mirror. That is. Since the other configuration is the same as that of the first embodiment, the description thereof is omitted.

As shown in FIG. 3, in the display device driver of the present embodiment, the gate signal line 8 that connects the gate electrode of the first current input MOSFET 10 and the gate electrode of the second current input MOSFET 12 is shown. , Resistors R ₁ and R ₂ , respectively, between the first current input MOSFET 10 and the first current mirror CM ₁ , between the gate electrodes of each current mirror, and between the current mirror C _n and the gate electrode of the second current input MOSFET. ,... R _n , R _{n + 1} are provided. Each of the resistors R ₁ , R ₂ ,... R _n , R _{n + 1} has a resistance value of about several kΩ to 10 kΩ, and is composed of, for example, polysilicon or a diffused resistor. The inventors of the present application have made a prototype of a display device driver with a 528 output in which the resistance value of each resistor is 2 kΩ (the overall resistance value is about 1 MΩ), and the operation has been confirmed.

  On the other hand, the resistance value of the gate signal line 8 connecting the current mirror in the LSI is about several Ω to several hundred Ω when a metal material such as Al (aluminum) is used.

  In the display device driver of the first embodiment shown in FIG. 1, when the resistance of the gate signal line 8 is low, the gate voltage Vgs of the MOSFETs constituting the current mirror group 9 has a substantially uniform voltage value inside the LSI. In some cases, it becomes impossible to cancel fluctuations in threshold variation.

  In contrast, in the display device driver of the present embodiment, a polysilicon resistor or a diffused resistor having a resistance value much higher than that of the metal wiring is provided between the gate electrodes of the current mirror. A voltage drop occurs in the mirror gate voltage. For this reason, if the display device driver of the present embodiment is used, it is possible to cancel the variation in the threshold value of the current mirror even when the resistance value of the metal wiring is low. Therefore, if the display device driver of this embodiment is used, variations in the output voltage of the drive voltage supply unit having the current mirror can be suppressed, so that the voltage drive type display device can be controlled without variations in luminance. .

  In the display device driver of the present embodiment, the resistance between the current mirrors may be made of a wiring itself made of a high resistance material such as polysilicon.

(Third embodiment)
As a third embodiment of the present invention, an example in which a plurality of display device driver LSI chips according to the second embodiment are connected will be described. In the following embodiments, the term “display device driver LSI” is used to represent a display device driver provided on one chip, but the circuit ranges shown are the first and second circuits. This is the same as the embodiment.

  FIG. 4 is a circuit diagram showing display device driver LSIs according to the second embodiment connected to each other. In the example shown in the figure, the chip provided with the first display device driver LSI 31 and the chip provided with the second display device driver LSI 32 are connected to each other by a current transmission path 38.

The first display device driver LSI 31 includes a first MOSFET 18a, a resistor 17a connected to the first MOSFET 18a, a first mirror 18a and a current mirror, and functions as a reference current source. (P-channel type) second MOSFET 19a, third MOSFET 21a and fourth MOSFET 23a, first current input MOSFET 10a connected to second MOSFET 19a, and second current connected to third MOSFET 21a An input MOSFET 12a, a first current input MOSFET 10a, a second current input MOSFET 12a, a current mirror group 9a constituting a current mirror, a gate electrode of the first current input MOSFET 10a, and a second current input MOSFET 12a With the gate electrode A gate signal line 8 to continue, a resistor R _1a disposed on the gate electrode _{8 ~R (n + 1) a} , is connected to the fourth MOSFET 23A, the reference to the adjacent second display driver LSI32 current Current transmission terminal 26a for outputting. That is, the first display device driver LSI 31 is different from the display device driver of the second embodiment in that the fourth MOSFET 23a for distributing the reference current and the current transmission terminal 26a are provided and adjacent to each other. The reference current can be transmitted to the driver LSI for display device. Note that the size of the fourth MOSFET 23a is equal to that of the second MOSFET 19a and the third MOSFET 21a. The fourth MOSFET 23a is preferably provided in the vicinity of the second MOSFET 19a and the third MOSFET 21a in order to make the electrical characteristics uniform. The distance between the third MOSFET 21a and the fourth MOSFET 23a is usually preferably 100 μm or less.

  The second display device driver LSI 32 has substantially the same configuration as that of the first display device driver LSI 31, but the first display device driver LSI 31 includes a first MOSFET 18a and a resistor 17a. A predetermined current is generated. On the other hand, in the second display device driver LSI 32, the gate electrode and the drain are connected to the first current input / output terminal 37 connected to the current transmission terminal 26 a and the first current input / output terminal 37. The second conductivity type (N-channel) fifth MOSFET 34, the sixth MOSFET 35 that forms a current mirror with the fifth MOSFET 34, and the seventh MOSFET 18b connected to the sixth MOSFET 35 are used as a reference. Current is transmitted. FIG. 4 shows an example in which the second display driver LSI does not have a current transmission terminal and a current mirror for transmitting a reference current to the current transmission terminal. These are provided when connecting the above display device driver LSIs.

  In the two display device driver LSIs shown in FIG. 4, since the size of the fourth MOSFET 23a is equal to that of the second MOSFET 19a and the third MOSFET 21a, the reference current is output from the third MOSFET 21a. Then, the reference current is input to the first current input / output terminal 37 via the current transmission terminal 26 a and the current transmission path 38. Then, if the size ratios of the fifth MOSFET 34 and the sixth MOSFET 35 constituting the current mirror and having the same size ratio are equal, the reference current is transmitted and input to the seventh MOSFET 18b. Then, when the size ratios of the seventh MOSFET 18b, the eighth MOSFET 19b, and the ninth MOSFET 21b are equal, the reference current is distributed to the eighth MOSFET 19b and the ninth MOSFET 21b and provided at both ends of the current mirror group 9b. A reference current is input to the third current input MOSFET 10b and the fourth current input MOSFET 12b. When the second display driver LSI 32 has a current transmission terminal and a current mirror for transmitting a reference current to the current transmission terminal, similarly, the reference current is applied to the adjacent display driver LSI. Can communicate.

  When the screen of the display device is large, a plurality of display device driver LSI chips are arranged. However, the characteristics of the transistors provided on different chips differ from those of the transistors provided on the same chip. Is often large. According to the display device driver LSI of the present embodiment, the reference current generated by the first display device driver LSI can be transmitted to both ends of the current mirror among the plurality of display device driver LSIs. Therefore, even when the threshold values of the MOSFETs constituting the current mirror group in the plurality of display device driver LSIs vary, substantially the same current can be output. Therefore, as in the present embodiment, by inputting an equal current to each of the plurality of display device driver LSIs to the current mirror group, a large-screen display panel can be driven without unevenness in luminance.

  In addition, compared with the conventional method of distributing the voltage to a plurality of display device driver LSIs, the display device driver LSI of this embodiment distributes current, so that the wiring inside the chip can be reduced.

  In the present embodiment, an example in which a plurality of display device driver LSIs according to the second embodiment are connected has been described, but the display device driver LSI according to the first embodiment can also be used.

(Fourth embodiment)
As a fourth embodiment of the present invention, another example of connecting a plurality of display device driver LSI chips according to the second embodiment will be described.

  FIG. 5 is a circuit diagram showing display device driver LSIs according to the second embodiment connected to each other. The display device driver LSI shown in FIG. 4 is different from the display device driver LSI shown in FIG. 4 in that a so-called cascode current mirror is provided between the first current input / output terminal 37 and the seventh MOSFET 18b. It is in the point provided. Since the other configuration is the same as that of the third embodiment, description thereof is omitted.

  5 includes a first current input / output terminal 37, a tenth MOSFET 43 whose drain and gate are connected to the first current input / output terminal 37, An eleventh MOSFET 44 that is cascode-connected to the source of the tenth MOSFET 43 and whose source is grounded, constitutes a current mirror with the tenth MOSFET 43, and a twelfth MOSFET 46 that has a drain connected to the drain of the seventh MOSFET 18b The cascode connection is made to the source of the twelfth MOSFET 46, and the eleventh MOSFET 44 and the thirteenth MOSFET 45 constituting the current mirror are provided. Further, the tenth MOSFET 43, the eleventh MOSFET 44, the twelfth MOSFET 46, and the thirteenth MOSFET 45 are all the second conductivity type (N channel type), and their W / L ratios are equal.

  With such a configuration, the constant current characteristic of the current mirror is improved, so that the occurrence of an error when propagating the reference current can be reduced as compared with the configuration of the current mirror shown in FIG. For this reason, since the output from the MOSFET constituting the current mirror group becomes uniform, the output current of the D / A converter having the current mirror group can also be made uniform. Therefore, by using the display device driver LSI of this embodiment, the uniformity of a display device such as a liquid crystal panel can be further improved.

  As the cascode current mirror that can be used for the display device driver LSI of this embodiment, there is a Wilson type current mirror other than the one shown in FIG.

(Fifth embodiment)
Since the display device driver LSIs according to the third and fourth embodiments have different configurations between the first display device driver and the second display device driver, two types of display device driver LSIs are provided. It is necessary to prepare.

  On the other hand, as a fifth embodiment of the present invention, a display device driver LSI capable of connecting a plurality of chips with only one type of chip will be described.

  FIGS. 6A and 6B are a circuit diagram showing the display device driver LSI of this embodiment, and a circuit diagram showing an example of the display device driver LSI of this embodiment when a plurality of display device driver LSIs are connected. is there. The drive voltage supply unit including the current mirror group is not shown. The same members as those in FIG. 5 are denoted by the same reference numerals.

  As shown in FIG. 6A, the display device driver LSI according to the present embodiment is configured by adding the first display device driver LSI 31 and the second display device driver LSI 41 shown in FIG. It has become. That is, the display device driver LSI of this embodiment is connected to the drain of the first MOSFET 18 (the seventh MOSFET 18b in FIG. 5) and the drain of the twelfth MOSFET 46, as compared with the second display device driver LSI 41. And a second current input / output terminal 53, a fourth MOSFET 23, and a current transmission terminal 52 connected to the drain of the fourth MOSFET 23 and connected to the display device driver in the next stage. Is different.

  With such a configuration, a plurality of display device driver LSIs of this embodiment can be connected as follows.

  As shown in FIG. 6B, the second current input / output terminal 53a of the first display device driver LSI 55 for generating a reference current is provided outside the chip and has a resistor 57 having one end grounded. Is connected. The first current input / output terminal 37a is grounded.

  By connecting to the outside in this way, a reference current is generated by the first MOSFET 18 a and the resistor 57. Here, since the gate electrode of the tenth MOSFET 43a and the gate electrode of the twelfth MOSFET 46 of the cascode type current mirror are both grounded, the tenth MOSFET 43a, the eleventh MOSFET 44, the twelfth MOSFET 46 and the thirteenth MOSFET are grounded. No current flows through the MOSFET 45.

  6B, the current transmission terminal 52a of the first display device driver LSI 55 and the first current input / output terminal 37b of the second display device driver LSI 56 are current transmission paths. Connected by Then, the second current input / output terminal 53b of the second display device driver LSI 56 is opened.

  By connecting the display device driver LSIs in this way, the reference current input to the first current input / output terminal 37b is transmitted to the seventh MOSFET 18b via the cascode current mirror. The reference current is transmitted from the fourth MOSFET 23b to the current transmission terminal 52b and output to the display device driver LSI in the next stage.

  Thereafter, the display device driver LSIs are cascade-connected in the same manner as the second display device driver LSI. As a result, substantially the same reference current is distributed to a plurality of chips.

  As described above, if the display device driver LSI of this embodiment is used, the display panel can be driven by only one type of chip, so that the manufacturing cost of the panel can be reduced.

  Here, the current mirror group in the D / A converter is an N-channel MOSFET, and it has been described on the assumption that current is drawn from the panel side. However, a current output type current mirror using a P-channel MOSFET is used. However, the same effect can be obtained. Furthermore, in the display device driver LSI of the present embodiment, the configuration in which the reference current output from the P-channel MOSFET is input to the N-channel MOSFET has been described. The same effect can be obtained when the generated current is limited to a constant current by the preceding N-channel transistor.

  When a plurality of display device driver LSIs are cascade-connected, a resistor having the same resistance value as that of the resistor 57 may be connected to the current transmission terminal 52 of the display device driver LSI at the final stage.

  A bipolar transistor can be used in place of the MOSFET included in the display device driver of the present embodiment.

  According to the display device driver or the display device of the present invention, variation in current flowing through each of the plurality of current mirrors can be suppressed, so that a current-driven or voltage-driven display panel can be driven without variation in luminance. It is useful for a display device driver and a display device for driving a display device such as a liquid crystal panel.

1 is a circuit diagram showing a display device driver according to a first embodiment of the present invention; The circuit diagram which shows the drive voltage supply part for 64 gradations among the drivers for display apparatuses which concern on 1st Embodiment. The circuit diagram which shows the driver for display apparatuses which concerns on the 2nd Embodiment of this invention The circuit diagram which shows the driver LSI for display apparatuses which concerns on 2nd Embodiment connected mutually The circuit diagram which shows another example of the driver LSI for display apparatuses based on 2nd Embodiment connected mutually (A) is a circuit diagram showing a display device driver LSI according to a fifth embodiment of the present invention, and (b) is a circuit showing an example of the display device driver LSI when a plurality of display device driver LSIs are connected. Figure (A) is a figure which shows schematically the structure of the display panel part of a liquid crystal display device, (b) is a circuit diagram which shows the structure of the conventional driver for display apparatuses, (c) is a display panel. Of variation in luminance

Explanation of symbols

8 Gate signal line 9, 9a, 9b Current mirror group 10, 10a First current input MOSFET
10b Third current input MOSFET
12, 12a Second MOSFET for current input
12b Fourth MOSFET for current input
17, 57 Resistor 18, 18a First MOSFET
18b 7th MOSFET
19, 19a Second MOSFET
19b Eighth MOSFET
21, 21a Third MOSFET
23, 23a, 23b Fourth MOSFET
26a Current transmission terminal 32 Second display device driver LSI
34 Fifth MOSFET
35 Sixth MOSFET
37, 37a, 37b First current input / output terminal 38 Current transmission path 43, 43a Tenth MOSFET
44, 44a, 44b Eleventh MOSFET
45, 45a, 45b 13th MOSFET
46, 46a, 46b 12th MOSFET
52, 52a, 52b Current transmission terminal 53b Second current input / output terminal 55 First display device driver LSI
CM ₁ first current mirror R _{1 to} R _n resistance L _{1 to} L _n switch

Claims (7)

A first reference current transistor of a first conductivity type for driving a reference current flowing in the first node;
A second reference current transistor of a first conductivity type for driving a reference current flowing through the second node;
A first current input transistor of a second conductivity type having a drain electrically connected to the first node, the gate electrode and the drain being electrically connected to each other;
The second node has a drain electrically connected, the gate electrode and the drain are electrically connected to each other, and the gate electrode is electrically connected to the gate electrode of the first current input transistor. A second current input transistor of the second conductivity type,
Each is disposed in a region sandwiched between the first current input transistor and the second current input transistor, and each gate electrode is a gate electrode of the first current input transistor and the second current input transistor. A plurality of current mirror transistors electrically connected to,
A display driver, comprising: a drive circuit that drives a display element in accordance with a current flowing through the plurality of current mirror transistors. The display device driver according to claim 1,
The display device driver, wherein the first reference current transistor and the second reference current transistor have the same W / L ratio. The display device driver according to claim 1,
A first conductive type first electrode having a gate electrode electrically connected to a gate electrode of each of the first reference current transistor and the second reference current transistor, wherein the drain and the gate electrode are electrically connected to each other; 1 transistor,
Both the first reference current transistor and the second reference current transistor constitute a current mirror circuit with the first transistor. The display device driver according to claim 1,
The wiring connecting the first reference current transistor and the first current input transistor and the wiring connecting the second reference current transistor and the second current input transistor have the same length and width. Characteristic display device driver. The display device driver according to claim 1,
Among the plurality of current mirror transistors, between the gate electrode of the current mirror transistor adjacent to the first current input transistor and the gate electrode of the first current input transistor, and among the plurality of current mirror transistors, Between the gate electrodes of two adjacent current mirror transistors, and among the plurality of current mirror transistors, a gate electrode of a current mirror transistor adjacent to the second current input transistor and a gate electrode of the second current input transistor, A driver for a display device, wherein a resistance element is provided between each of the resistors. In the display device driver according to claim 1 or 5 ,
A gate electrode electrically connected to the gate electrodes of the first reference current transistor and the second reference current transistor, and a size of W / L with the first reference current transistor and the second reference current transistor A third reference current transistor of the first conductivity type having the same ratio;
The display driver, further comprising a current transmission terminal electrically connected to a drain of the third reference current transistor. In the display device driver according to claim 1 or 5 ,
A first conductive type first electrode having a gate electrode electrically connected to a gate electrode of each of the first reference current transistor and the second reference current transistor, wherein the drain and the gate electrode are electrically connected to each other; One transistor,
A first current input / output terminal for transmitting a reference current;
A second transistor of the second conductivity type having a drain electrically connected to the first current input / output terminal, the drain and the gate electrode being electrically connected to each other;
For a display device, further comprising: a second transistor of a second conductivity type having a drain electrically connected to the first transistor and forming a current mirror circuit with the second transistor. driver.

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