JP6186337B2 - Display device and display driving method - Google Patents

Description

  The present invention relates to a display device and a display driving method, and more particularly, to a display panel driving technique in which a plurality of data lines and scanning lines are arranged and pixels are formed corresponding to the intersections of the data lines and the scanning lines.

JP 2000-293245 A

As a display panel for displaying an image, a display device using an OLED (Organic Light Emitting Diode), a display device using an LCD (Liquid Crystal Display), and the like are known. In many display devices, a plurality of data lines commonly connected to a plurality of pixels arranged in the column direction and a plurality of scanning lines commonly connected to a plurality of pixels arranged in the row direction are provided, and the data lines and the scans are arranged. It has a display portion in which pixels are formed corresponding to each intersection of lines.
In the case of so-called line sequential scanning, the data line driver outputs a data line driving signal for one line to each data line while the scanning line driver sequentially selects the scanning lines, so that each dot as a pixel is output. The display is controlled.

  In Patent Document 1, the data line driver is a constant current driver, and a reference current for generating a constant current output to each data line is generated by a reference current generation circuit using an external reference resistor of the IC. The structure to perform is disclosed.

  Here, for example, as a passive matrix driving OLED display device, a driving method is considered in which constant current driving is performed on a data line, and gradation is controlled by the width (on period) of a constant current data line driving signal. The constant current value as the data line drive signal corresponds to the reference current value generated by the reference current generation circuit. For this reason, when the reference current value varies, the constant current value of the data line drive signal varies. . The fluctuation of the data line driving signal is visually recognized as a luminance change on the display panel.

One of the major factors that cause fluctuations in the reference current is radio noise. If there is a radio noise source in the vicinity of the display device, the voltage applied to the reference resistor that determines the reference current by application of radio noise fluctuates, and the reference current value fluctuates accordingly. That is, there is a problem that the luminance change on the display panel is caused by the radio wave noise.
An object of the present invention is to realize a display device that reduces such luminance change due to radio noise and has good display performance.

The display device according to the present invention includes a plurality of data lines commonly connected to a plurality of pixels arranged in the column direction and a plurality of scanning lines commonly connected to the plurality of pixels arranged in the row direction, A display unit in which pixels are formed corresponding to each intersection of the data line and the scanning line, a scanning line driving unit for supplying a scanning line driving signal to each of the scanning lines, and data for each of the data lines as a line drive signal, a data line driver for outputting a time length only constant current according to the gradation values of the pixels defined by the display data, the reference current defining a current value before Symbol data line driving signals, reference A first current adjusting unit that generates a constant current according to the voltage; and a second current adjusting unit that is connected to the current path of the reference current and is a constant current circuit using an active element.
A constant current reference current is generated by the first current adjustment unit as a constant current circuit, and the reference current is stabilized by the second current adjustment unit so as to reduce fluctuation due to radio noise.

The first current adjusting portion is provided in an integrated circuit including at least the data line drive unit, the second current adjusting unit is so provided we are outside the integrated circuit.
Since the second current adjustment unit is connected to the current path of the reference current, the second current adjustment unit is arranged outside the integrated circuit to have a function as an external reference resistor for setting the reference current value. Particularly in this case, since the influence of radio noise is increased by the wiring outside the integrated circuit, it is preferable to stabilize the reference current by the second current adjustment unit.

In addition, the first current adjustment unit may be configured such that the reference voltage is equivalent to the reference voltage so that the operational amplifier performs negative feedback based on the reference voltage, and the voltage at the connection point with the second current adjustment unit is equal to the reference voltage. It is configured to determine the current value of the current,
In the second current adjustment unit, a transistor element and a resistor are connected in series between a connection point of the first current adjustment unit and the ground, and a control terminal of the transistor element is connected to a voltage node obtained by dividing a fixed voltage. It is the composition which is.
With this circuit configuration, the resistance value and the voltage value at the connection point between the first current adjustment unit and the second current adjustment unit are stabilized even when there is radio noise.

In the display driving method according to the present invention, a plurality of data lines commonly connected to a plurality of pixels arranged in the column direction and a plurality of scanning lines commonly connected to a plurality of pixels arranged in the row direction are respectively disposed. A display unit in which pixels are formed corresponding to each intersection of the data line and the scanning line, a scanning line driving unit for supplying a scanning line driving signal to each of the scanning lines, and each of the data lines The data line driving signal is provided in an integrated circuit including at least the data line driving unit, a data line driving unit that outputs a constant current for a time length corresponding to a gradation value of a pixel defined by display data, A circuit that generates a reference current that defines a current value of a data line drive signal as a constant current according to a reference voltage, wherein the operational amplifier performs negative feedback with respect to the reference voltage and is connected to a negative feedback path. A first current configured to determine a current value of the reference current based on the reference voltage and the external resistance component by applying a voltage equivalent to the reference voltage to the external resistance component outside the product circuit. As a display driving method for a display device including an adjustment unit , an active element serving as the external resistance component outside the integrated circuit is used for a terminal provided in the negative feedback path which is a current path of the reference current. A second current adjusting unit, which is a constant current circuit, and a transistor element and a resistor are connected in series between a connection point of the first current adjusting unit and the ground. The control terminal is configured to be connected to a voltage node obtained by dividing a fixed voltage so that the reference current generated by the first current adjustment unit is adjusted by the second current adjustment unit , The group Is obtained as a current value of the data line driving signals are defined by the current.
That is, this is a display driving method that reduces the fluctuation of the reference current that defines the constant current value of the data line driving signal due to radio noise.

  According to the present invention, it is possible to reduce fluctuations in display brightness caused by external radio noise, and it is possible to provide a display device with good display quality.

1 is a block diagram of a display device and an MPU according to an embodiment of the present invention. It is a block diagram in the controller IC of the embodiment. FIG. 6 is an explanatory diagram equivalently showing an anode driver, a cathode driver, and a pixel in the display device of the embodiment. It is explanatory drawing of the circuit structure regarding the constant current output from the anode driver of embodiment. It is explanatory drawing of the circuit for the production | generation of the reference current of a comparative example and embodiment. It is explanatory drawing of the modification of the 2nd electric current adjustment part of embodiment.

Embodiments of the present invention will be described below.
FIG. 1 shows a display device 1 according to an embodiment and an MPU (Micro Processing Unit) 2 that performs display operation control of the display device 1.
The display device 1 includes a display unit 10 that constitutes a display screen, a controller IC (Integrated Circuit) 20, and a cathode driver 21.

The display unit 10 includes a plurality of data lines DL and scanning lines SL, and pixels are formed corresponding to the intersections of the data lines DL and the scanning lines SL. For example, 256 data lines DL1 to DL256 and 128 scanning lines SL1 to SL128 are arranged, and accordingly, 256 pixels are arranged in the horizontal direction and 128 pixels are arranged in the vertical direction. The
Accordingly, the display unit 10 has 256 × 128 = 32768 pixels as pixels constituting the display image. In the case of this embodiment, each pixel is formed as a self-luminous element using an OLED. Of course, the number of pixels, the number of data lines, and the number of scanning lines are merely examples.
Each of the 256 data lines DL1 to DL256 is commonly connected to 128 pixels arranged in the column direction (vertical direction) of the display unit 10. Each of the 128 scanning lines SL1 to SL128 is commonly connected to 256 pixels arranged in the row direction (horizontal direction).
A data line driving signal based on display data (gradation value) is supplied from the data line DL to 256 pixels of the line selected by the scanning line SL, so that each pixel of the line corresponds to the display data. Light emission is driven with luminance (gradation).
The “line” is used to mean a unit of 256 pixels connected to one scanning line or one scanning line.

A controller IC 20 and a cathode driver 21 are provided for driving the display unit 10.
The controller IC 20 includes a drive control unit 31, a display data storage unit 32, and an anode driver 33. The anode driver 33 drives the data lines DL1 to DL256. The anode driver 33 is an example of the data line driving unit described in the claims.
In the case of this example, the anode driver 33 receives a pulse signal (drive control signal ADS) having a time length corresponding to the gradation from the drive control unit 31, and in a period specified by the drive control signal ADS. A constant current is output to the data line DL. A constant current signal applied to the data line DL is referred to as a “data line drive signal”.
That is, the display device 1 of this example is a passive matrix drive OLED display device, and performs constant current drive on the data line DL, and drives the gray scale to be controlled by the width (on period) of the constant current data line drive signal. Adopt the method.

In order to generate a constant current output from the anode driver 33 to the data line DL, a first current adjustment unit 33a and a second current adjustment unit 50 are provided.
As an example of the embodiment, the first current adjusting unit 33a is a circuit unit mounted inside the anode driver 33 (in this example, the integrated circuit as the controller IC 20), and the second current adjusting unit 50 is The circuit is composed of elements externally attached to the controller IC 20. However, the 1st electric current adjustment part 33a does not necessarily need to be inside the controller IC20. In some cases, the anode driver 33 may be formed of a chip (integrated circuit) separate from the controller IC 20 having the drive control unit 31. In that case, it is assumed that the first current adjusting unit 33 a is provided in an integrated circuit as the anode driver 33.

The drive control unit 31 communicates commands and display data with the MPU 2 and controls display operations according to the commands. For example, when receiving a display start command, the drive control unit 31 performs timing setting in response thereto, gives a cathode driver control signal CA to the cathode driver 21, and starts scanning the scanning line SL. In synchronization with scanning by the cathode driver 21, the anode driver 33 drives the 256 data lines DL.
Regarding the driving of the data line DL by the anode driver 33, the drive control unit 31 stores the display data received from the MPU 2 in the display data storage unit 32, and at the same time as the scanning timing, a drive control signal based on the display data. ADS is supplied to the anode driver 33. In response to this, the anode driver 33 outputs a data line driving signal corresponding to the gradation to the data line DL.
By such control, each pixel on the selected line, that is, one scanning line SL to which a scanning signal of a selection level is given from the cathode driver 21 is driven to emit light. By sequentially driving each line to emit light, frame image display is realized.

The cathode driver 21 functions as a scanning line driving unit that applies a scanning signal from one end of the scanning line SL.
The cathode driver 21 is arranged with its Q1 output terminal to Q128 output terminal connected to the scanning lines SL1 to SL128, respectively. Then, as indicated by the scanning direction SD, a scanning signal of a selection level is sequentially output from the Q1 output terminal to the Q128 output terminal, thereby performing scanning in which the scanning lines SL1 to SL128 are sequentially selected.

Each part of the display device 1 of FIG. 1 will be described in detail.
First, FIG. 2 shows the inside of the controller IC 20, but particularly shows the inside of the drive control unit 31 in detail.
In the drive control unit 31, an MPU interface 41, a command decoder 42, an oscillation circuit 43, and a timing controller 44 are provided.

The MPU interface 41 is an interface circuit unit that performs various communications with the MPU 2 described above. Specifically, display data, command signals, and brightness setting values are transmitted and received between the MPU interface 41 and the MPU 2.
The command decoder 42 takes in the command signal transmitted from the MPU 2 into an internal register (not shown) and decodes the command signal. Then, the command decoder 42 makes a necessary notification to the timing controller 44 in order to execute an operation according to the contents of the fetched command signal. The command decoder 42 stores the fetched display data in the display data storage unit 32.

The oscillation circuit 43 generates a clock signal CK for display drive control.
The clock signal CK is supplied to the display data storage unit 32 and used as a clock for data write / read operations. The clock signal CK is used for processing of the timing controller 44.

The timing controller 44 sets driving timings for the scanning lines SL and the data lines DL of the display unit 10. Then, the timing controller 44 outputs a cathode driver control signal CA to cause the cathode driver 21 to perform line scanning.
The timing controller 44 also outputs a drive control signal ADS to the anode driver 33 to drive the data line DL (constant current output as a data line drive signal). Further, for this operation, display data is read from the display data storage unit 32, and a drive control signal ADS is generated based on the display data. As a result, the anode driver 33 outputs a constant current (data line drive signal) corresponding to the drive control signal to each pixel of the corresponding line in accordance with the scanning timing of each scanning line SL.

Next, FIG. 3 shows the configuration of the display unit 10, the anode driver 33, and the cathode driver 21 as an equivalent circuit.
As shown in FIG. 3, in the display unit 10, a pixel G is arranged at each intersection of the scanning line SL and the data line DL, and a display image is formed by the pixels G arranged in a matrix. In FIG. 3, the pixel G is indicated by a diode symbol representing an organic EL element and a capacitance symbol representing a parasitic capacitance.

  The cathode driver 21 is provided with switches SWC1 to SWC128 for selecting whether the scanning lines SL1 to SL128 are connected to the voltage VHC or the ground, respectively. The unselected scanning line SL is connected to the voltage VHC, and the selected scanning line SL to be scanned is connected to the ground. That is, in this case, the scanning signal at the selection level is in the ground potential state. By sequentially connecting the scanning lines SL1 to SL128 to the ground, the scanning lines SL1 to SL128 are sequentially selected.

In the anode driver 33, constant current sources I1 to I256 and switches SWA1 to SWA256 are provided corresponding to the data lines DL1 to DL256.
For each of the data lines DL1 to DL256, a constant length from the constant current sources I1 to I256 is set for the 256 pixels G of the scanning line SL in the selected state for a period length corresponding to each display data (gradation value). The switches SWA1 to SWA256 are controlled by the drive control signal ADS so that a current (data line drive signal) is supplied.

FIG. 4 shows a more specific configuration example in which the anode driver 33 supplies a constant current data line driving signal with a set current value to the data lines DL1 to DL256 only during a period corresponding to the gradation of each pixel. Show.
The anode driver 33 is provided with a current output unit 33b that actually supplies a constant current to the data lines DL1 to DL256 and the above-described first current adjustment unit 33a.

The first current adjustment unit 33 a includes an operational amplifier 81 and a P-channel FET (Field Effect Transistor) 82.
A fixed reference voltage VR (for example, 1.2 V) is applied to the inverting input of the operational amplifier 81. The non-inverting input of the operational amplifier 81 is connected from the terminal 20T of the controller IC 20 including the anode driver 33 to the second current adjustment unit 50 (terminal 52) via the external wiring 60.
The output terminal of the operational amplifier 81 is connected to the gate of the FET 82, the source of the FET 82 is connected to the voltage VHA, and the drain is connected to the non-inverting input of the operational amplifier 81.

  In other words, the first current adjustment unit 33a is a constant current circuit using the operational amplifier 81, applies negative feedback with reference to the reference voltage VR, and is equivalent to the reference voltage VR with respect to the external resistance component connected to the terminal 20T. The circuit operates so that a voltage is applied. A reference current IR corresponding to the reference voltage VR flows between the source and drain of the FET 82. The current value of the reference current IR is the value of the resistor connected to the outside from the terminal 20T and the voltage applied to the resistor (ie, the terminal). It is determined by the value of voltage between 20T and ground≈reference voltage VR).

The wiring 60 from the terminal 20T is connected to the terminal 52 of the second current adjusting unit 50. The collector / emitter of the bipolar transistor 51 and the resistor R1 are connected in series between the terminal 52 and the ground. Specifically, the terminal 52 is connected to the collector of the bipolar transistor 51, the emitter of the bipolar transistor 51 is connected to one end of the resistor R1, and the other end of the resistor R1 is connected to the ground.
The base (control terminal) of the bipolar transistor 51 is connected to a voltage node obtained by dividing a voltage between the fixed voltage VHB and the ground by the resistor R2, the resistor R3, and the diode D1.
That is, the second current adjusting unit 50 is a constant current circuit using an active element connected to the current path of the reference current IR. The function of the second current adjusting unit 50 will be described later.

  The current output unit 33b of the anode driver 33 has a P channel functioning as a switching element for switching between a state in which the data line DL is connected to the current source and a state in which the data line DL is connected to the ground, corresponding to the data lines DL1 to DL256. An FET 86, an N-channel FET 87, and a P-channel FET 85 for supplying a constant current as the data line drive signal Idr are provided.

  Each FET 85 has a source connected to the voltage VHA and a drain connected to the FET 86. The gate of each FET 85 is connected to the output terminal of the operational amplifier 81 together with the gate of the FET 82.

When the FET 86 as the switch element is turned on and the FET 87 is turned off, the data lines DL1 to DL256 are connected to the drains of the FETs 85. Further, when the FET 86 is turned off and the FET 87 is turned on, the data lines DL1 to DL256 are connected to the ground.
In this case, the FET 82 and each FET 85 adopt a current mirror configuration. Therefore, when the FET 86 is on and the FET 87 is off, the data line driving signal Idr that is a constant current signal having a current value of the reference current IR is supplied to the data line DL.
The FETs 86 and 87 are turned on / off by a drive control signal ADS from the drive control unit 31. In this case, a constant current is supplied to the data line DL when the drive control signal ADS is at the L (Low) level, and the data line DL is grounded when the drive control signal ADS is at the H (High) level.

  As can be understood from the above configuration, first, the constant current value as the data line drive signal Idr given to the data line DL is defined by the reference current IR obtained by the first current adjustment unit 33a. The period during which the data line drive signal is applied to the data line DL is controlled by the drive control signal ADS. Accordingly, the drive control signal ADS is a pulse signal having a period length corresponding to the gradation value, whereby the constant current (data line drive signal Idr) supply period to the data line DL is controlled according to the gradation value. As a result, the pixel G emits light with luminance corresponding to the gradation.

  4 and the anode driver 33 shown in FIG. 3, the set of FETs 86 and 87 in FIG. 4 corresponds to the switches SWA1 to SWA256 in FIG. It can be said that each part corresponds to the constant current sources I1 to I256 of FIG.

Here, referring to FIG. 5A, a method of generating a reference current IR as a comparative example will be described.
FIG. 5A shows an example in which a reference resistor R100 is externally connected to the first current adjustment unit 33a. Even in such a configuration, a reference current IR as a constant current can be obtained. That is, the current value of the reference current IR is determined by the value of the reference resistor R100 and the voltage applied to the reference resistor R100 (≈reference voltage VR).
(Current value of reference current IR) = (value of reference voltage VR) / (value of reference resistance R100)
It is calculated by the following formula.

  However, when external radio noise is applied to the wiring including the external reference resistor R100, the voltage applied to the reference resistor R100 fluctuates due to the influence, and the reference current IR fluctuates. As a result, the constant current value as the data line drive signal Idr changes, and as a result, the screen brightness of the display unit 10 varies. That is, if there is a radio wave noise source in the vicinity of the display device 1, the luminance variation of the display screen occurs and the display quality deteriorates.

Therefore, in the present embodiment, the second current adjusting unit 50 is provided as shown in FIG. 4 in place of the external reference resistor R100. The second current adjustment unit 50 is a constant current circuit. Therefore, the configuration of FIG. 4 is a second current which is a constant current circuit using an active element (bipolar transistor 51) connected to the current path of the reference current IR generated by the constant current circuit (first current adjustment unit 33a). The adjustment unit 50 is provided.
The second current adjustment unit 50 operates so that a constant current flows even if the terminal voltage fluctuates due to the influence of radio wave noise. For this reason, it is possible to suppress the reference current IR from fluctuating due to the influence of radio wave noise. As a result, the current value fluctuation of the data line drive signal Idr is suppressed, and the luminance change on the display is reduced. Therefore, the display device 1 according to the present embodiment can reduce display luminance fluctuation caused by external radio noise, and can obtain good display quality.

  In the embodiment, the first current adjustment unit 33 a is provided in the controller IC 20, and the second current adjustment unit 50 is a circuit externally attached to the controller IC 20 via the wiring 60. In other words, the reference current IR is set by the resistance value and voltage in the external resistance component. In this case, the influence of radio noise is increased by the wiring 60 outside the integrated circuit. Therefore, it is very preferable to stabilize the reference current IS by adopting a configuration in which the reference resistor R100 as shown in FIG. 5A is replaced with the second current adjusting unit 50.

  In the embodiment, in the first current adjustment unit 33a, the operational amplifier 81 performs negative feedback with reference to the reference voltage VR, and the voltage at the connection point with the second current adjustment unit 50 is equal to the reference voltage VR. Thus, the current value of the reference current IR is determined, and the second current adjustment unit 50 includes a transistor element (bipolar transistor 51) between a connection point (terminal 52) with the first current adjustment unit 33a and the ground. And the resistor R1 are connected in series, and the control terminal of the transistor element (the base of the bipolar transistor 51) is connected to a voltage node obtained by dividing the fixed voltage VHB. With this circuit configuration, the resistance value and the voltage value at the connection point between the first current adjusting unit 33a and the second current adjusting unit 50 are stabilized even when there is radio noise.

Here, FIG. 5B shows a more specific configuration example of the second current adjusting unit 50 shown in FIG.
In FIG. 5B, a resistor corresponding to the resistor R2 in FIG. 4 is formed by connecting the resistors R21 and R22 in series. Further, a resistor corresponding to the resistor R3 in FIG. 4 is formed by connecting the resistors R31 and R32 in parallel. Reference voltage VR = 1.2V and voltage VHA = VHB = 3.3V. An example of each element in this case is given.
Resistor R1: 22 kΩ
Resistor R21: 27 kΩ
Resistor R22: 180 kΩ
Resistor R31: 33 kΩ
Resistor R32: 22 kΩ
Diode D1: 1SS187
Bipolar transistor 51: 2SC2712

Feedback is applied to the terminal 52 through which the reference current IR flows as a connection point with the first current adjustment unit 33a so as to be 1.2V. The reference current IR is 12 μA.
The circuit on the base side of the bipolar transistor 51 (VHB = 3.3 V power supply) is also set to have a current of 12 μA. This is because temperature compensation is performed by the diode D1, but the accuracy is increased.
In order to apply simple feedback to the emitter-base voltage (0.5 V) of the bipolar transistor 51, a resistor R1 is added. If the resistance value of the resistor R1 is large, a feedback effect can be easily obtained. However, since the voltage is required, the operating voltage of the bipolar transistor 51 is insufficient. The resistance R1 = 22 kΩ is selected from the balance between the operating voltage of the bipolar transistor 51 and the feedback effect. The voltage applied to the resistor R1 is 0.264V.
The bipolar transistor 51 is set to flow 12 μA. The base voltage is targeted at about 0.764V. Since the base current is about hFE = 100, it is 0.12 μA, which is almost negligible and is not considered.
The voltage across the diode D1 is 0.6V. Therefore, the combined resistance of the resistors R31 and R32 is adjusted to (0.764V−0.6V) ÷ 12 μA = 13.7 kΩ as a target.
The combined resistance of the resistors R21 and R22 is adjusted to (3.3V−0.764V) ÷ 12 μA = 211 kΩ as a target.

It is conceivable to select the above-mentioned constants by designing from such a viewpoint.
The circuit configuration and constants of the second current adjustment unit 50 are examples that can suitably cope with a case where the reference voltage VR is a low voltage such as 1.2V.

  Although the embodiment has been described above, the display device of the present invention is not limited to the embodiment, and various modifications can be considered.

Various other examples of the configuration of the second current adjusting unit 50 are conceivable. In particular, when the reference voltage VR is high, the degree of freedom in circuit design increases. For example, circuit examples that can be employed as the second current adjusting unit 50 are illustrated in FIGS. 6A, 6B, 6C, and 6D.
In the example of FIG. 6A, the collector / emitter of the bipolar transistor 52 and the resistor R11 are connected in series between the terminal 52 and the ground, and the base of the bipolar transistor 52 is connected to the connection point of the resistor R12 and the collector of the bipolar transistor 53. The base of the bipolar transistor 53 is connected to the connection point between the resistor R11 and the emitter of the bipolar transistor 52. That is, it is a feedback type constant current circuit.
In the example of FIG. 6B, the collector / emitter of the bipolar transistor 54 and the resistor R21 are connected in series between the terminal 52 and the ground, and the base of the bipolar transistor 54 is connected to the connection point of the resistor R22 and the cathode of the Zener diode ZD.
In the example of FIG. 6C, the collector / emitter of the bipolar transistor 55 and the resistor R31 are connected in series between the terminal 52 and the ground, the base of the bipolar transistor 55 is connected to the connection point of the resistor R32 and the diode ZD31, and the diodes D31 and D32 are connected. Are connected in series.
In the example of FIG. 6D, the drain / source of the FET 56 and the resistor R41 are connected in series between the terminal 52 and ground, and the gate of the FET 56 is connected to a voltage dividing point by the resistors R42 and R43.
Since any of these circuits functions as a constant current circuit, the reference current IR can be stabilized by using the second current adjustment unit 50.

Although the controller IC 20 shown in FIG. 1 includes the anode driver 33, the anode driver 33 may be a separate body. Further, both the anode driver 33 and the cathode driver 21 may be built in the controller IC 20.
The present invention is applicable not only to display devices using OLEDs but also to other types of display devices. It is particularly suitable for a display device using a self-luminous element driven by current.

1. Display device 2. MPU
10: Display unit 20 ... Controller IC
DESCRIPTION OF SYMBOLS 31 ... Drive control part 32 ... Display data memory | storage part 33 ... Anode driver 33a ... 1st electric current adjustment part 50 ... 2nd electric current adjustment part

Claims (3)

A plurality of data lines commonly connected to the plurality of pixels arranged in the column direction and a plurality of scanning lines commonly connected to the plurality of pixels arranged in the row direction are provided, and each of the data lines and the scanning lines is arranged. A display part in which pixels are formed corresponding to the intersection;
A scanning line driving unit for supplying a scanning line driving signal to each of the scanning lines;
A data line driving unit that outputs a constant current for a time length corresponding to a gradation value of a pixel defined by display data as a data line driving signal for each of the data lines ;
A circuit that is provided in an integrated circuit including at least the data line driving unit and generates a reference current that defines a current value of the data line driving signal as a constant current according to a reference voltage, and an operational amplifier generates the reference voltage By applying negative feedback as a reference and applying a voltage equivalent to the reference voltage to the external resistance component outside the integrated circuit connected to the negative feedback path, the reference voltage and the external resistance component A first current adjustment unit configured to determine a current value of the reference current;
A constant current circuit using an active element connected to the negative feedback path which is a current path of the reference current and serving as the external resistance component and provided outside the integrated circuit, the first current adjusting unit and A transistor element and a resistor connected in series between the connection point and the ground, and a control terminal of the transistor element includes a second current adjustment unit configured to be connected to a voltage node obtained by dividing a fixed voltage. apparatus. The first current adjustment unit is configured to vary a current value of the reference current in response to the reference voltage being varied according to a control signal.
The display device according to claim 1 . A plurality of data lines commonly connected to the plurality of pixels arranged in the column direction and a plurality of scanning lines commonly connected to the plurality of pixels arranged in the row direction are provided, and each of the data lines and the scanning lines is arranged. A display part in which pixels are formed corresponding to the intersection;
A scanning line driving unit for supplying a scanning line driving signal to each of the scanning lines;
A data line driving unit that outputs a constant current for a time length corresponding to a gradation value of a pixel defined by display data as a data line driving signal for each of the data lines;
A circuit that is provided in an integrated circuit including at least the data line driving unit and generates a reference current that defines a current value of the data line driving signal as a constant current according to a reference voltage, and an operational amplifier generates the reference voltage By applying negative feedback as a reference and applying a voltage equivalent to the reference voltage to the external resistance component outside the integrated circuit connected to the negative feedback path, the reference voltage and the external resistance component A first current adjustment unit configured to determine a current value of the reference current;
As a display driving method for a display device comprising:
A terminal provided in the negative feedback path that is a current path of the reference current is connected to a second current adjustment unit that is a constant current circuit using an active element that is the external resistance component outside the integrated circuit;
In the second current adjustment unit, a transistor element and a resistor are connected in series between a connection point of the first current adjustment unit and the ground, and a control terminal of the transistor element is connected to a voltage node obtained by dividing a fixed voltage. With the configuration, the reference current generated by the first current adjustment unit is adjusted by the second current adjustment unit ,
A display driving method in which a current value of the data line driving signal is defined by the reference current.

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