KR102399370B1 - Pixel and Display comprising pixels - Google Patents

Abstract

The present embodiments disclose a pixel and a display device including the same.
In a display device according to an embodiment of the present invention, each of a plurality of subframes constituting one frame includes a data writing period and a light emitting period, and the pixel circuit of the pixel includes: m A memory for receiving and storing a corresponding bit string among bit strings of a plurality of n-bit data generated by a combination of n bits smaller than m among m bits constituting a bit string of bit data, and each subframe a first pixel circuit including a controller configured to generate a control signal based on n bit values and n clock signals of the stored corresponding bit string during the light emission period; and a second pixel circuit for controlling light emission and non-emission of the light emitting device in response to the control signal during the light emission period of each subframe.

Description

Pixel and Display comprising pixels

The present embodiments relate to a pixel and a display device including the same.

As the information society develops, the demand for a display device that displays an image is increasing, and a liquid crystal display device, a plasma display device, and an organic light emitting display device are increasing. Various types of display devices such as, etc. are being used. Recently, interest in a display device using a micro light emitting diode (μLED) (hereinafter referred to as a “micro display device”) is also increasing.

As excellent display device characteristics are required for VR (Virtual Reality), AR (Augmented Reality), and MR (Mixed Reality) technologies, the development of micro LED on Silicon or AMOLED on Silicon is on the rise. Demand for minimization is increasing.

SUMMARY OF THE INVENTION An embodiment of the present invention provides a display device capable of reducing power consumption and implementing good matching characteristics.

A pixel according to an embodiment of the present invention includes a light emitting device and a pixel circuit connected to the light emitting device, and each of a plurality of subframes constituting one frame includes a data write period and a light emission period, and the pixel circuit In the data writing period of each subframe, a corresponding one of a plurality of bit strings of n-bit data generated by a combination of n bits smaller than m among m bits constituting a bit string of m-bit data a first pixel circuit comprising: a memory for receiving and storing a bit string; and a controller for generating a control signal based on n bit values and n clock signals of the stored corresponding bit string during the light emission period of each subframe; and a second pixel circuit for controlling light emission and non-emission of the light emitting device in response to the control signal during the light emission period of each subframe.

The number of bit strings of the n-bit data is the same as the number of subframes, the light emission period of each subframe is the sum of time allocated to each bit of the corresponding bit string, and the n-bit data includes: It is a combination of n bits among the m bits in which the difference between the light emission periods is minimized.

In an embodiment, the n is (m/2)+1 or (m/2)-1, and two bit strings among the bit strings of the n-bit data are at least one of the bit strings of the m-bit data. may include a specific bit of as a common bit, and the time allocated to the common bit may be half of the time allocated to the specific bit in the bit string of the m-bit data.

In an embodiment, the n is m/2, and the bit streams of the n-bit data do not include a bit at the same position among the m bits, and each bit of the bit strings of the n-bit data is The sum of allotted time may approximate each other.

The first pixel circuit may include: a first transistor for outputting a driving current; a second transistor that transmits or blocks the driving current to the light emitting device according to the control signal; and a level shifter converting the voltage level of the control signal.

A display device according to an embodiment of the present invention includes: a pixel unit in which a plurality of pixels including a light emitting element and a pixel circuit connected to the light emitting element are arranged; A plurality of bit streams of n-bit data are generated by a combination of n bits smaller than m among m bits constituting a bit string of m-bit data, and the plurality of subframes constituting one frame a data driver for outputting a corresponding bit string from among the plurality of bit strings of n-bit data to the pixel; and a clock generator for supplying a clock signal to the pixel in response to each bit of the corresponding bit string for each subframe including the data writing period and the light emission period.

The pixel circuit of the pixel receives and stores the corresponding bit string in the data writing period of each subframe, and in the light emission period of each subframe, n bit values of the stored corresponding bit string and n clock signals a first pixel circuit generating a control signal based on and a second pixel circuit for controlling light emission and non-emission of the light emitting device in response to the control signal during the light emission period of each subframe.

The number of bit streams of the n-bit data is the same as the number of subframes, the light emission period of each subframe is the sum of time allocated to each bit of the corresponding bit string, and the n-bit data includes: It may be a combination of n bits among the m bits in which a difference between light emission periods is minimized.

In an embodiment, the n is (m/2)+1 or (m/2)-1, and two bit strings among the bit strings of the n-bit data are at least one of the bit strings of the m-bit data. may include a specific bit of as a common bit, and the time allocated to the common bit may be half of the time allocated to the specific bit in the bit string of the m-bit data.

In an embodiment, the n is m/2, and the bit streams of the n-bit data do not include a bit at the same position among the m bits, and each bit of the bit strings of the n-bit data is The sum of allotted time may approximate each other.

A display device according to an embodiment of the present invention can reduce power consumption and implement a pixel circuit having good matching characteristics. In addition, the display device according to the embodiment of the present invention can implement a pixel circuit having a small size while minimizing the time difference between subframes.

1 is a diagram schematically illustrating a manufacturing process of a display device according to an exemplary embodiment of the present invention.
2 and 3 are diagrams schematically illustrating a display device according to an embodiment of the present invention.
4 is a diagram for explaining data division according to an embodiment of the present invention.
5 is a diagram illustrating an example of time allocated to bits according to an embodiment of the present invention.
6 is a circuit diagram illustrating a current supply unit according to an embodiment of the present invention.
7 is a circuit diagram illustrating a pixel PX according to an exemplary embodiment.
8 is a diagram for explaining driving of a pixel according to another embodiment of the present invention.
9 is a diagram for explaining bit data division according to an embodiment of the present invention.
FIG. 10 is a view for explaining a driving timing of a clock signal according to the embodiment of FIG. 9 .
11 is a diagram for explaining bit data division according to another embodiment of the present invention.
12 is a view for explaining a driving timing of a clock signal according to the embodiment of FIG. 11 .
13 is a diagram for explaining bit data division according to another embodiment of the present invention.
14 is a view for explaining a driving timing of a clock signal according to another embodiment of FIG. 13 .

Since the present invention can apply various transformations and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. Effects and features of the present invention, and a method for achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, and when described with reference to the drawings, the same or corresponding components are given the same reference numerals, and the overlapping description thereof will be omitted. .

In the following embodiments, terms such as first, second, etc. are used for the purpose of distinguishing one component from another, not in a limiting sense. Also, in the following examples, the singular expression includes the plural expression unless the context clearly dictates otherwise.

In the following embodiments, when X and Y are connected, X and Y are electrically connected, X and Y are functionally connected, and X and Y are directly connected. can Here, X and Y may be objects (eg, devices, elements, circuits, wirings, electrodes, terminals, conductive films, layers, etc.). Therefore, it is not limited to a predetermined connection relationship, for example, the connection relationship shown in the drawings or detailed description, and may include other than the connection relationship shown in the drawings or detailed description.

When X and Y are electrically connected, for example, an element (for example, a switch, a transistor, a capacitor, an inductor, a resistance element, a diode, etc.) that enables the electric connection of X and Y is, It may include a case in which one or more is connected between X and Y.

When X and Y are functionally connected, a circuit that enables the functional connection of X and Y (for example, a logic circuit (OR gate, inverter, etc.) , signal conversion circuits (AD conversion circuits, gamma correction circuits, etc.), potential level conversion circuits (level shifter circuits, etc.), current supply circuits, amplifier circuits (circuits that can increase signal amplitude or current amount, etc.), signal generation circuits, A case in which one or more memory circuits (memory, etc.) are connected between X and Y may be included.

In the following embodiments, “ON” used in connection with a device state may refer to an activated state of the device, and “OFF” may refer to an inactive state of the device. As used in connection with a signal received by a device, “on” may refer to a signal that activates a device, and “off” refers to a signal that deactivates a device. The device can be activated by a high voltage or a low voltage. For example, a P-type transistor is activated by a low voltage, and an N-type transistor is activated by a high voltage. Accordingly, it should be understood that the "on" voltages for a P-type and N-type transistor are opposite (low vs. high) voltage levels.

In the following embodiments, terms such as include or have means that the features or components described in the specification are present, and the possibility that one or more other features or components will be added is not excluded in advance.

1 is a diagram schematically illustrating a manufacturing process of a display device according to an exemplary embodiment of the present invention.

Referring to FIG. 1 , a display device 30 according to an exemplary embodiment may include a light emitting device array 10 and a driving circuit board 20 . The light emitting device array 10 may be coupled to the driving circuit board 20 .

The light emitting device array 10 may include a plurality of light emitting devices. The light emitting device may be a light emitting diode (LED). At least one light emitting device array 10 may be manufactured by growing a plurality of light emitting diodes on the semiconductor wafer SW. Accordingly, the display device 30 may be manufactured by combining the light emitting device array 10 with the driving circuit board 20 without individually transferring the light emitting diodes to the driving circuit board 20 .

A pixel circuit corresponding to each of the light emitting diodes on the light emitting device array 10 may be arranged on the driving circuit board 20 . The light emitting diode on the light emitting device array 10 and the pixel circuit on the driving circuit board 20 may be electrically connected to form the pixel PX.

2 and 3 are diagrams schematically illustrating a display device according to an embodiment of the present invention.

2 and 3 , the display device 30 may include a pixel unit 110 and a driver 120 .

The pixel unit 110 may display an image using an m-bit digital image signal capable of displaying 1 to 2 ^m gray scales. The pixel unit 110 may include a plurality of pixels PX arranged in various patterns such as a predetermined pattern, for example, a matrix type or a zigzag type. The pixel PX emits one color, for example, one color among red, blue, green, and white. The pixel PX may emit colors other than red, blue, green, and white.

The pixel PX may include a light emitting device. The light emitting device may be a self-luminous device. For example, the light emitting device may be a light emitting diode (LED). The light emitting device may be a light emitting diode (LED) having a micro to nano unit size. The light emitting device may emit light at a single peak wavelength or may emit light at a plurality of peak wavelengths.

The pixel PX may further include a pixel circuit connected to the light emitting device. The pixel circuit may include at least one thin film transistor and at least one capacitor. The pixel circuit may be implemented by a semiconductor stacked structure on a substrate.

The pixel PX may operate in units of frames. One frame may be composed of a plurality of subframes. Each subframe may include a data writing period and a light emission period. During the data writing period, digital data of a predetermined bit may be applied to and stored in the pixel PX. A predetermined bit of digital data stored in the light emission period is read out in synchronization with a clock signal, and the digital data is converted into a PWM signal so that the pixel PX can express a gray level. The light emission period of the subframe may be the sum of time allocated to each bit of digital data.

The driving unit 120 may drive and control the pixel unit 110 . The driving unit 120 may include a control unit 121 , a gamma setting unit 123 , a data driving unit 125 , a current supply unit 127 , and a clock generation unit 129 .

The controller 121 receives input image data DATA1 of one frame from an external (eg, graphic controller), receives a correction value from the gamma setting unit 123, and uses the correction value to input image data ( Correction image data DATA2 may be generated by performing gamma correction on DATA1).

4 is a diagram illustrating data division according to an embodiment of the present invention, and FIG. 5 is a diagram illustrating an example of time allocated to bits according to an embodiment of the present invention.

Referring to FIG. 4 , the controller 121 extracts a grayscale for each pixel PX from the corrected image data DATA of one frame, and converts the extracted grayscale to a digital value of a predetermined number of bits (eg, m bits). can be converted to data.

The controller 121 may divide m-bit data into p pieces of n-bit data smaller than m. Here, p may be the number of subframes. p may be a number less than n. The controller 121 may generate bit streams of a plurality of n-bit data by combining n bits smaller than m among m bits constituting a bit stream of m-bit data. When one frame consists of two subframes, the controller 121 may generate two bit streams of n-bit data from a bit string of m-bit data.

A detailed description of bit stream division and distribution will be described later.

The m-bit data may be a bit string including m bit values from a most significant bit (MSB) to a least significant bit (LSB). The bit value may have any one of a first logic level and a second logic level. The first logic level and the second logic level may be a high level and a low level, respectively. Alternatively, the first logic level and the second logic level may be a low level and a high level, respectively.

Referring to FIG. 5 , a time set for each bit of m-bit data may be different. For example, the most significant bit (MSB) is assigned the longest first time (T/2), and the second most significant bit (MSB-1) is assigned the second time (T/2 ² ), in such a way that the least significant bit ( LSB) the shortest m-th time (T/2 ^m )) may be allocated. The sum of the time allocated to each bit of m-bit data may be equal to or close to the time T allocated to one frame.

In one embodiment, n may be (m/2)+1 or (m/2)-1. Two of the bit streams of the n-bit data may include at least one specific bit in the bit string of the m-bit data as a common bit. The time allocated to the common bit may be half of the time allocated to the specific bit in the bit string of m-bit data. For example, when p is 2, the controller 121 may divide 10-bit data into two 6-bit data or three 4-bit data. Each of the two 6-bit data may include at least one of a 10-bit most significant bit (MSB) and a second significant bit (MSB-1) as a common bit. The time allocated to the common bit of the two 6-bit data may be half the time allocated to the most significant bit (MSB) and/or the second most significant bit (MSB-1) of 10 bits. Two 4-bit data of the three 4-bit data may include at least one of a 10-bit most significant bit (MSB) and a next-most significant bit (MSB-2) as a common bit. The time allocated to the common bit of the two 6-bit data may be half the time allocated to the most significant bit (MSB) and/or the second most significant bit (MSB-1) of 10 bits.

In another embodiment, n may be m/2. The bit streams of the n-bit data may not include bits at the same position among the m bits, and the sum of time allocated to each bit of the bit streams of the n-bit data may be close to each other. For example, when p is 2, the controller 121 may divide 10-bit data into two 5-bit data. At this time, each bit of the two 5-bit data does not overlap with each other.

The control unit 121 may distribute the divided p pieces of n-bit data to the p subframes and output them to the data driver 125 . The time (length) of the subframe may be equal to the sum of the time allocated to each bit of n-bit data. The time allocated to each bit of n-bit data may be the time allocated to the corresponding position in the bit string of m-bit data or a half thereof. The time of subframes may be the same or different. The controller 121 may generate a plurality of n-bit data by combining the bits of the m-bit data so that the time difference between the subframes (in particular, the difference between the emission periods of the subframes) is minimized. The control unit 121 divides the time allocated to at least one of the most significant bit (MSB), the next most significant bit (MSB-1), and the next most significant bit (MSB-2) to which the longest time is allocated in the m-bit data to obtain a plurality of n Bit data can be generated.

The gamma setting unit 123 may set a gamma value using a gamma curve, set a correction value of image data according to the set gamma value, and output the set correction value to the controller 121 . The gamma setting unit 123 may be provided as a circuit separate from the control unit 121 , or may be provided to be included in the control unit 121 .

The data driver 125 may receive m-bit data in units of subframes from the controller 121 and transmit it to each pixel PX of the pixel unit 110 .

The data driver 125 may include a line buffer and a shift register circuit. The line buffer may be a one-line buffer or a two-line buffer. The data driver 125 may provide n-bit data to each pixel for each subframe in line units (row units).

The current supply unit 127 may generate and supply a driving current of each pixel PX. The configuration of the current supply unit 127 will be described later with reference to FIG. 6 .

The clock generator 129 may generate n clock signals for each subframe during one frame and output them to the pixels PX. The n clock signals may be outputted corresponding to each bit of m-bit data. The signal width (length or ON time) of the clock signal may be determined according to a time allocated to each bit of m-bit data. The clock generator 129 may sequentially supply n clock signals to the clock line CL for each subframe.

Each component of the driving unit 120 is formed in the form of a separate integrated circuit chip or one integrated circuit chip, and is mounted directly on the substrate on which the pixel unit 110 is formed, or on a flexible printed circuit film. It may be mounted, attached to a substrate in the form of a tape carrier package (TCP), or directly formed on the substrate. In an embodiment, the control unit 121 , the gamma setting unit 123 , and the data driver 125 are connected to the pixel unit 110 in the form of an integrated circuit chip, and the current supply unit 127 and the clock generation unit 129 . may be formed directly on the substrate.

6 is a circuit diagram illustrating a current supply unit according to an embodiment of the present invention.

Referring to FIG. 6 , the current supply unit 127 may include a first transistor 51 , a second transistor 53 , an operational amplifier 55 , and a variable resistor 57 .

The first transistor 51 has a gate connected to the pixel PX, a first terminal connected to a source voltage VDD, and a second terminal connected to a gate and a first terminal of the second transistor 55 . .

The second transistor 53 has a gate connected to the output terminal of the operational amplifier 55 , a first terminal connected to a second terminal of the first transistor 51 , and a second terminal connected to the second terminal of the operational amplifier 55 . It is connected to the input terminal (-).

The first input terminal (+) of the operational amplifier 55 is connected to the source of the reference voltage Vref, and the second input terminal (-) is connected to the variable resistor 57 . The output terminal of the operational amplifier 55 is connected to the gate of the second transistor 53 . When the reference voltage Vref is applied to the first input terminal (+), the second transistor 53 is turned on or can be turned off.

A resistance value of the variable resistor 57 may be determined according to a control signal SC from the controller 121 . The output terminal voltage of the operational amplifier 55 is changed according to the resistance value of the variable resistor 57 , and the current Iref flowing through the first transistor 51 and the second transistor 53 turned on from the power supply voltage VDD can be determined.

The current supply unit 127 may supply a driving current corresponding to the current Iref to the pixel PX by configuring a transistor and a current mirror in the pixel PX. The driving current may determine the overall luminance (brightness) of the pixel unit 110 .

Although the above-described embodiment shows an example in which the current supply unit 127 includes a first transistor 51 implemented as a P-type transistor and a second transistor 53 implemented as an N-type transistor, the embodiment of the present invention The present invention is not limited thereto, and the current supply unit 127 may be configured by implementing the first transistor 51 and the second transistor 53 as different types of transistors and configuring an operational amplifier corresponding thereto.

7 is a circuit diagram illustrating a pixel PX according to an exemplary embodiment.

Referring to FIG. 7 , the pixel PX may include a pixel circuit including a light emitting device ED and a first pixel circuit 40 and a second pixel circuit 50 connected thereto. The first pixel circuit 40 may be a low voltage driving circuit, and the second pixel circuit 50 may be a high voltage driving circuit. The first pixel circuit 40 may be implemented as a plurality of logic circuits.

The light emitting device ED selectively emits or does not emit light based on the bit value (logic level) of the image data provided from the data driver 125 for each subframe during one frame, so that the light emission time is adjusted within one frame to increase the grayscale. can be displayed

The first pixel circuit 40 stores the bit values of n-bit data applied from the data driver 125 in the data writing period for each subframe, and the first pixel circuit 40 based on the n bit values and n clock signals in the light emission period. A PWM signal can be generated. The first pixel circuit 40 may include a PWM controller 401 and a memory 403 .

The PWM controller 401 may generate the first PWM signal based on the clock signal CK input from the clock generator 120 and the bit value of the image data read from the memory 403 during the light emission period. When a clock signal is input from the clock generator 120 , the PWM controller 401 may read a corresponding image data bit value from the memory 403 to generate a first PWM signal.

The PWM controller 401 may control the pulse width of the first PWM signal based on the bit value of the image data and the signal width of the clock signal in units of subframes. For example, if the bit value of the image data is 1, the pulse output of the PWM signal is turned on by the signal width of the clock signal, and if the bit value of the image data is 0, the pulse output of the PWM signal is turned off by the signal width of the clock signal. there is. That is, the on time of the pulse output of the PWM signal and the off time of the pulse output may be determined by the signal width (signal length) of the clock signal. The PWM controller 401 may include one or a plurality of logic circuits (eg, an OR gate circuit, etc.) implemented with one or a plurality of transistors.

The memory 403 may receive n-bit data applied through the data line DL from the data driver 125 during the data writing period for each subframe in synchronization with the subframe start signal and store the n-bit data in advance. In the case of a still image, image data previously stored in the memory 403 may be continuously used for image display for a plurality of frames until the image is updated or refreshed.

Bit values (logic levels) of n-bit data may be input from the data driver 125 to the memory 403 in a predetermined order. The memory 403 may store at least 1-bit data. In one embodiment, memory 403 may be an n-bit memory. In the memory 403 , n-bit values of n-bit data may be written during the data writing period of the subframe. The memory 403 may be implemented with one or a plurality of transistors. Memory 503 may be implemented with random access memory (RAM), for example, SRAM or DRAM.

When the m-bit data is applied to the memory 403 without conversion, the memory 403 must have a capacity to store the m-bit data, which may be a constraint on the size of the pixel. When the memory 403 has a 1-bit capacity, since the pixel has to be driven in a plurality of subframes, the driving frequency increases, and the current consumption due to the increase in the driving frequency increases, which may be a limiting factor in the case of a battery-using product. . In addition, a different time must be allocated for each subframe. On the other hand, in the embodiment of the present invention, by using an n-bit memory smaller than m bits for the memory 403, the memory capacity can be reduced, thereby reducing the pixel size. In addition, by using the n-bit memory, the number of subframes can be reduced compared to that of the 1-bit memory, so that the driving frequency can be properly maintained.

The second pixel circuit 50 may control light emission and non-emission of the light emitting device ED in response to a control signal applied from the first pixel circuit 40 to each of the plurality of subframes during one frame. The control signal may be a PWM signal. The second pixel circuit 50 may include a first transistor 501 , a second transistor 503 , and a level shifter 505 electrically connected to the current supply unit 127 .

The first transistor 501 may output a driving current. The first transistor 501 has a gate connected to the current supply unit 127 , a first terminal connected to a power supply voltage source VDD, and a second terminal connected to a first terminal of the second transistor 503 . The gate of the first transistor 501 may be connected to the gate of the first transistor 51 of the current supply unit 127 to form a current supply unit 127 and a current mirror circuit. Accordingly, as the first transistor 51 of the current supply unit 127 is turned on, the turned-on first transistor 501 may supply a driving current corresponding to the current Iref formed in the current supply unit 127 . The driving current may be the same as the current Iref flowing through the current supply unit 127 .

The second transistor 503 may transmit or block the driving current to the light emitting device ED according to the PWM signal. The second transistor 503 has a gate connected to an output terminal of the level shifter 505 , a first terminal connected to a second terminal of the first transistor 501 , and a second terminal connected to the light emitting device ED .

The second transistor 503 may be turned on or off according to a voltage output from the level shift 505 . The emission time of the light emitting device ED may be adjusted according to the turn-on or turn-off time of the second transistor 503 . The second transistor 503 is turned on when a gate-on level signal (low level in the embodiment of FIG. 7 ) is applied to the gate, and the driving current Iref output from the first transistor 501 is applied to the light emitting device ED. It can be transmitted so that the light emitting device ED emits light. The second transistor 503 is turned off when a gate-off level signal (high level in the embodiment of FIG. 7 ) is applied to the gate, so that the driving current Iref output from the first transistor 501 is applied to the light emitting device ED. The light emitting device ED may not emit light by blocking the light from being transmitted. The light emitting time and non-emission time of the light emitting device ED are controlled by the turn-on time and turn-off time of the second transistor 503 during one frame, so that the color depth of the pixel unit 110 can be expressed. there is.

The level shifter 505 is connected to the output terminal of the PWM (Pulse Width Modulation) controller 401 of the first pixel circuit 40 and converts the voltage level of the first PWM signal output by the PWM controller 401 to convert the second A PWM signal can be generated. The level shifter 505 converts the first PWM signal into a gate-on voltage level signal capable of turning on the second transistor 503 and a gate-off level signal capable of turning off the second transistor 503 , a second PWM signal can be generated. When the first PWM signal output by the PWM controller 401 is sufficient to drive the second transistor 503 , the level shifter 505 may be omitted.

The pulse voltage level of the second PWM signal output from the level shifter 505 may be higher than the pulse voltage level of the first PWM signal, and the level shifter 505 may include a boosting circuit for boosting the input voltage. The level shifter 505 may be implemented with a plurality of transistors.

The turn-on time and turn-off time of the second transistor 503 for one frame may be determined according to the pulse width of the first PWM signal.

In the embodiment of FIG. 7 , the current supply unit 127 is connected to one pixel PX, but the current supply unit 127 may be shared by the plurality of pixels PX. For example, as shown in FIG. 8 , the first transistor 51 of the current supply unit 127 is electrically connected to the first transistor 501 of each of all the pixels PX of the pixel unit 110 . A current mirror circuit can be constructed. In another embodiment, a current supply unit 127 may be provided for each row, and the current supply unit 127 of each row may be shared by a plurality of pixels PX in the same row.

Although the above-described embodiment shows an example in which the pixel is composed of P-type transistors, the embodiment of the present invention is not limited thereto, and the pixel is composed of N-type transistors, and in this case, the pixel is applied with P-type transistors. It can be driven by a signal whose level is inverted.

9 is a diagram for explaining bit data division according to an embodiment of the present invention, and FIG. 10 is a diagram for explaining a driving timing of a clock signal according to an embodiment of the present invention. 10 is a driving timing of a clock signal applied to the first row.

9 and 10 show an example in which one frame is composed of two subframes, and a PWM signal is generated by two 6-bit data generated by dividing 10-bit data in each subframe.

Referring to FIG. 9 , the leftmost bit of 1 of the bit string 1011100110 of 10-bit data of the pixel PX is the MSB, and the rightmost bit, 0, is the LSB. 10-bit data may be divided into two bit strings of 6-bit data. The difference between the time of the first subframe SF1 and the time of the second subframe SF2, specifically, the light emission period ET of the first subframe SF1 and the light emission period SF2 of the second subframe SF2 ET), the bits may be combined to minimize the difference.

The first 6-bit data is a combination 101110 of MSB*/MSB-1*/MSB-2/MSB-7/MSB-8/LSB of 10-bit data. The second 6-bit data is a combination 101100 of MSB*/MSB-1*/MSB-3/MSB-4/MSB-5/MSB-6 of 10-bit data. Here, '*' indicates that half (1/2) of the time allocated in 10-bit data is allocated to the corresponding bit. That is, 1, which is the leftmost bit of the first 6-bit data and the second 6-bit data, is 1, which is the most significant bit (MSB) of 10-bit data, a common bit obtained from the same location of 10-bit data, and half the time allocated to the MSB divided and assigned to each. Similarly, the 0, which is the second left bit of the first 6-bit data and the second 6-bit data, is the 0, which is the second significant bit (MSB-1) of the 10-bit data, is a common bit obtained from the same position of 10-bit data, and is assigned to MSB-1 Half of the time allotted to each is divided.

The first (left) 6-bit data is image data of the first subframe SF1, and the second (right) 6-bit data is image data of the second subframe SF2.

Referring to FIG. 10 , the pixel PX may be driven in a data writing period DT and an emission period ET for each subframe of one frame. Since the ON time of the light emission period ET constitutes the main time of the subframe, the time of the subframe and the time of the light emission period may be used interchangeably below. The time of the first subframe and the time of the second subframe may be different but approximate.

In the data writing period DT of the first subframe SF1 , a bit value of n-bit data from the data driver 125 may be written (stored) to the memory 503 in the pixel PX. That is, the first 6-bit data bit stream 101110 of FIG. 9 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the first subframe SF1 , the first to sixth clock signals CK1 to CK6 are applied to the PWM controller 501 in synchronization with 6-bit data, and the PWM controller 501 A PWM signal may be generated based on a bit value of 6-bit data written in the memory 503 and the first to sixth clock signals CK1 to CK6 .

Each of the first to sixth clock signals CK1 to CK6 of the first subframe SF1 may be applied at the same time as the time allocated to each bit of 6-bit data. For example, the first clock signal CK1 is applied for 1/2 x (T/2), which is half of the time T/2 allocated to the MSB, and the second clock signal CK2 is applied to the MSB-1. It is applied for 1/2 x (T/2 ² ), which is half of the allocated time (T/2 ² ), and the third clock signal CK3 is applied for the time (T/2 ³ ) allocated to MSB-2, , the fourth clock signal CK4 is applied for a time (T/2 ⁸ ) assigned to MSB-7, and the fifth clock signal CK5 is applied for a time (T/2 ⁹ ) assigned to MSB-8, , the sixth clock signal CK6 may be applied for a time T/2 ¹⁰ allocated to the LSB.

In the data writing period DT of the second subframe SF2 , a bit value of n-bit data from the data driver 125 may be written to the memory 503 in the pixel PX. That is, the second 6-bit data bit string 101100 of FIG. 9 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the second subframe SF2 , the first to sixth clock signals CK1 to CK6 are applied to the PWM controller 501 in synchronization with 6-bit data, and the PWM controller 501 A PWM signal may be generated based on a bit value of 6-bit data written in the memory 503 and the first to sixth clock signals CK1 to CK6 .

Each of the first to sixth clock signals CK1 to CK6 of the second subframe SF2 may be applied at the same time as a time allocated to each bit of 6-bit data. For example, the first clock signal CK1 is applied for 1/2 x (T/2), which is half of the time T/2 allocated to the MSB, and the second clock signal CK2 is applied to the MSB-1. It is applied for 1/2 x (T/2 ² ), which is half of the allocated time (T/2 ² ), and the third clock signal CK3 is applied for the time (T/2 ⁴ ) allocated to MSB-3, and , the fourth clock signal CK4 is applied for a time T/2 ⁵ allocated to MSB-4, and the fifth clock signal CK5 is applied for a time T/2 ⁶ allocated to MSB-5, and , the sixth clock signal CK6 may be applied for a time T/2 ⁷ allocated to MSB-6.

In each of the first subframe SF1 and the second subframe SF2 , the PWM controller 501 reads a bit value of 6-bit data from the memory 503 , the signal width of the clock signal CK and the bit data You can control the pulse width of the PWM signal based on the bit value of . The PWM controller 501 may generate the PWM signal PWM based on the clock signal CK output to the first subframe SF1 and the second subframe SF2 and the bit value of the bit data.

11 is a diagram for explaining bit data division according to another embodiment of the present invention, and FIG. 12 is a diagram for explaining a driving timing of a clock signal according to another embodiment of the present invention. 12 is a driving timing of a clock signal applied to the first row.

11 and 12 show an example in which one frame is composed of three subframes, and a PWM signal is generated by three 4-bit data generated by dividing 10-bit data in each subframe.

Referring to FIG. 11 , 1, which is the leftmost bit, of the bit string 1011100110 of 10-bit data of the pixel PX, is the MSB, and 0, which is the rightmost bit, is the LSB. 10-bit data can be divided into three 4-bit data. The bit data may be combined to minimize the difference in time between the first to third subframes SF1 to SF3, specifically, the difference in the light emission period ET of the first to third subframes SF1 to SF3. there is.

The first 4-bit data is a combination 1110 of MSB*/MSB-2*/MSB-4/LSB of 10-bit data. The second 4-bit data is a combination 1101 of MSB*/MSB-2*/MSB-5/MSB-8 of 10-bit data. The third 4-bit data is a combination of 10-bit data MSB-1/MSB-3/MSB-6/MSB-7 (0101). Here, '*' indicates that half (1/2) of the time allocated in 10-bit data is allocated to the corresponding bit. That is, 1, which is the leftmost bit of the first 4-bit data and the second 4-bit data, is 1, which is the most significant bit (MSB) of 10-bit data. divided and assigned to each. Similarly, 1, the second left bit of the first 6-bit data and the second 6-bit data, is 1, which is the third bit (MSB-2) of 10-bit data, which is a common bit taken from the same position of 10-bit data, and is in MSB-2 Each is allocated in half of the allotted time.

The first (left) 4-bit data is image data of the first subframe SF1, the first (center) 4-bit data is image data of the second subframe SF2, and the third (right) 4-bit data is image data of the third subframe SF3.

Referring to FIG. 12 , the pixel PX may be driven in a data writing period DT and an emission period ET for each subframe of one frame. The time of the first subframe and the time of the second subframe may be different but approximate.

In the data writing period DT of the first subframe SF1 , a bit value of n-bit data from the data driver 125 may be written to the memory 503 in the pixel PX. That is, the first 4-bit data bit stream 1110 of FIG. 11 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the first subframe SF1 , the first to fourth clock signals CK1 to CK4 are applied to the PWM controller 501 in synchronization with 4-bit data, and the PWM controller 501 is The PWM signal may be generated based on the bit value of the 4-bit data written in the memory 503 and the first to fourth clock signals CK1 to CK4 .

Each of the first to fourth clock signals CK1 to CK4 of the first subframe SF1 may be applied at the same time as the time allocated to each bit of the 4-bit data. For example, the first clock signal CK1 is applied for 1/2 x (T/2), which is half of the time T/2 allocated to the MSB, and the second clock signal CK2 is applied to the MSB-2. It is applied for 1/2 x (T/2 ³ ), which is half of the allocated time (T/2 ³ ), and the third clock signal CK3 is applied for the time (T/2 ⁵ ) allocated to MSB-4, and , the fourth clock signal CK4 may be applied for a time T/2 ¹⁰ allocated to the LSB.

In the data writing period DT of the second subframe SF2 , a bit value of n-bit data from the data driver 125 may be written to the memory 503 in the pixel PX. That is, the second 4-bit data bit string 1101 of FIG. 11 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the second subframe SF2 , the first to fourth clock signals CK1 to CK4 are applied to the PWM controller 501 in synchronization with 4-bit data, and the PWM controller 501 is The PWM signal may be generated based on the bit value of the 4-bit data written in the memory 503 and the first to fourth clock signals CK1 to CK4 .

Each of the first to fourth clock signals CK1 to CK4 of the second subframe SF2 may be applied at the same time as the time allocated to each bit of the 4-bit data. For example, the first clock signal CK1 is applied for 1/2 x (T/2), which is half of the time T/2 allocated to the MSB, and the second clock signal CK2 is applied to the MSB-2. It is applied for 1/2 x (T/2 ³ ), which is half of the allocated time (T/2 ³ ), and the third clock signal CK3 is applied for the time (T/2 ⁶ ) allocated to MSB-5, , the fourth clock signal CK4 may be applied for a time T/2 ⁹ allocated to MSB-8.

In the data writing period DT of the third subframe SF3 , a bit value of n-bit data from the data driver 125 may be written to the memory 503 in the pixel PX. That is, the third 4-bit data bit string 0101 of FIG. 11 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the third subframe SF3 , the first to fourth clock signals CK1 to CK4 are applied to the PWM controller 501 in synchronization with 4-bit data, and the PWM controller 501 The PWM signal may be generated based on the bit value of the 4-bit data written in the memory 503 and the first to fourth clock signals CK1 to CK4 .

Each of the first to fourth clock signals CK1 to CK4 of the third subframe SF3 may be applied at the same time as the time allocated to each bit of the 4-bit data. For example, the first clock signal CK1 is applied for a time allocated to MSB-1 (T/2 ² ), and the second clock signal CK2 is applied for a time allocated to MSB-3 (T/2 ⁴ ) is applied, the third clock signal CK3 is applied for a time allocated to MSB-6 (T/2 ⁷ ), and the fourth clock signal CK4 is applied for a time allocated to MSB-7 (T/2 ⁸ ) may be authorized during

In each of the first to third subframes SF1 to SF3 , the PWM controller 501 reads the bit value of 4-bit data from the memory 503 , the signal width of the clock signal CK and the bit value of the bit data It is possible to control the pulse width of the PWM signal based on The PWM controller 501 may generate the PWM signal PWM based on the clock signal CK output from the first to third subframes SF1 to SF3 and the bit value of the bit data.

13 is a diagram for explaining bit data division according to another embodiment of the present invention, and FIG. 14 is a diagram for explaining a driving timing of a clock signal according to another embodiment of the present invention. 14 is a driving timing of a clock signal applied to the first row.

13 and 14 show an example in which one frame is composed of two subframes, and a PWM signal is generated by two 5-bit data generated by dividing 10-bit data in each subframe.

Referring to FIG. 13 , the leftmost bit of 1 of the bit string 1011100110 of 10-bit data of the pixel PX is the MSB, and the rightmost bit, 0, is the LSB. 10-bit data can be divided into two 5-bit data. The difference between the time of the first subframe SF1 and the time of the second subframe SF2, specifically, the light emission period ET of the first subframe SF1 and the light emission period SF2 of the second subframe SF2 The bits may be combined to minimize the difference in ET).

The first 5-bit data is a combination 10110 of MSB/MSB-6/MSB-7/MSB-8/LSB of 10-bit data. The second 5-bit data is a combination (01110) of MSB-1/MSB-2/MSB-3/MSB-4/MSB-5 of 10-bit data.

The first (left) 5-bit data is image data of the first subframe SF1, and the second (right) 5-bit data is image data of the second subframe SF2.

Referring to FIG. 14 , the pixel PX may be driven in a data writing period DT and an emission period ET for each subframe of one frame. The ON time of the light emission period ET is the time of the subframe, and the time of the first subframe and the time of the second subframe are different but may be approximate.

In the data writing period DT of the first subframe SF1 , a bit value of n-bit data from the data driver 125 may be written to the memory 503 in the pixel PX. That is, the first 5-bit data bit string 10110 of FIG. 13 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the first subframe SF1 , the first to fifth clock signals CK1 to CK5 are applied to the PWM controller 501 in synchronization with 5-bit data, and the PWM controller 501 is A PWM signal may be generated based on a bit value of 5-bit data written in the memory 503 and the first to fifth clock signals CK1 to CK5 .

Each of the first to fifth clock signals CK1 to CK6 of the first subframe SF1 may be applied at the same time as the time allocated to each bit of the 5-bit data. For example, the first clock signal CK1 is applied for a time T/2 allocated to the MSB, and the second clock signal CK2 is applied for a time T/2 ⁷ allocated to the MSB-6. , the third clock signal CK3 is applied for a time T/2 ⁸ assigned to MSB-6, and the fourth clock signal CK4 is applied for a time T/2 ⁸ assigned to MSB-7, and , the fifth clock signal CK5 may be applied for a time T/2 ¹⁰ allocated to the LSB.

In the data writing period DT of the second subframe SF2 , a bit value of n-bit data from the data driver 125 may be written to the memory 503 in the pixel PX. That is, the second 5-bit data bit string 01110 of FIG. 13 may be written to the memory 503 in the pixel PX.

In the light emission period ET of the second subframe SF2 , the first to fifth clock signals CK1 to CK5 are applied to the PWM controller 501 in synchronization with 5-bit data, and the PWM controller 501 A PWM signal may be generated based on a bit value of 5-bit data written in the memory 503 and the first to fifth clock signals CK1 to CK5 .

Each of the first to fifth clock signals CK1 to CK5 of the second subframe SF2 may be applied at the same time as the time allocated to each bit of the 5-bit data. For example, the first clock signal CK1 is applied for a time allocated to MSB-1 (T/2 ² ), and the second clock signal CK2 is applied for a time allocated to MSB-2 (T/2 ³ ) is applied, the third clock signal CK3 is applied for a time allocated to MSB-3 (T/2 ⁴ ), and the fourth clock signal CK4 is applied for a time allocated to MSB-4 (T/2 ⁵ ) is applied, and the fifth clock signal CK5 may be applied for a time T/2 ⁶ allocated to MSB-5.

In each of the first subframe SF1 and the second subframe SF2 , the PWM controller 501 reads a bit value of 5-bit data from the memory 503 , the signal width of the clock signal CK and the bit data You can control the pulse width of the PWM signal based on the bit value of . The PWM controller 501 may generate the PWM signal PWM based on the clock signal CK output to the first subframe SF1 and the second subframe SF2 and the bit value of the bit data.

9 to 14 , when the bit value is 1, the PWM controller 501 may output a pulse having a pulse width equal to the signal width of the clock signal CK. When the bit value is 0, the PWM controller 501 may not output a pulse equal to the signal width of the clock signal CK. In another embodiment, when the bit value is 1, the PWM controller 501 does not output a pulse equal to the signal width of the clock signal CK, but when the bit value is 0, the PWM controller 501 has a pulse width equal to the signal width of the clock signal CK It is possible to output a pulse with

The light emitting device ED may emit light or non-emission according to the pulse output of the PWM signal during one frame. When the pulse output is turned on, the light emitting device ED may emit light for a time corresponding to the pulse width. The light emitting device ED may not emit light as long as the pulse output is turned off.

An embodiment of the present invention may be implemented as a micro LED display device.

A pixel according to an embodiment of the present invention includes a pixel circuit for switching a current source for driving a current, and the switching signal may be generated by a combination of a timing signal representing a gray level (grayscale) and digital data.

The pixel according to an embodiment of the present invention can reduce the number of memory bits required per pixel by dividing and storing digital data in a plurality of subframes within one frame.

In the embodiment of the present invention, the memory is provided in the pixel to enable current driving, and since the driving unit only needs to transmit a simple driving pulse to the pixel unit in a still image, power consumption can be improved.

According to the embodiment of the present invention, excellent matching characteristics between pixels can be secured by using a high bias current at a low gray scale by PWM driving, and a high color depth can be realized even with a small pixel size.

According to an embodiment of the present invention, a desired gamma value can be set through digital processing, and the luminance can be easily adjusted using a current mirror circuit while maintaining the set gamma value.

According to the embodiment of the present invention, a high-resolution display device can be realized with a circuit configuration centered on low-voltage transistors.

In the present specification, the present invention has been described with reference to limited embodiments, but various embodiments are possible within the scope of the present invention. In addition, although not described, it will be said that equivalent means are also combined as it is in the present invention. Therefore, the true scope of protection of the present invention should be defined by the following claims.

Claims (2)

In a pixel comprising a light emitting device and a pixel circuit connected to the light emitting device,
Each of the plurality of subframes constituting one frame includes a data writing period and a light emission period,
The pixel circuit is
In the data writing period of each subframe, a corresponding bit string among a plurality of bit strings of n-bit data generated by a combination of n bits smaller than m among m bits constituting a bit string of m-bit data a first pixel circuit comprising: a memory for receiving and storing ; and
a second pixel circuit for controlling light emission and non-emission of the light emitting device in response to the control signal during the light emission period of each subframe;
The n-bit data corresponds to a bit string in which n bits of the m bits are combined such that a difference between light emission periods of the plurality of subframes is minimized. The method of claim 1, wherein the first pixel circuit comprises:
a first transistor for outputting a driving current;
a second transistor that transmits or blocks the driving current to the light emitting device according to the control signal; and
A pixel including; a level shifter for converting the voltage level of the control signal.

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