This U.S. Non-provisional application claims priority under 35 USC § 119 to Korean Patent Application No. 10-2017-0063947, filed on May 24, 2017, in the Korean Intellectual Property Office (KIPO), the disclosure of which is incorporated by reference in its entirety herein.
Some example embodiments relate to semiconductor integrated circuits, and more particularly to display panels having a zigzag connection structure and/or display devices including the same.
Power consumption of a display device may increase as size and/or resolution of a display panel included in the display device increase. The power consumption of the display device may include static power consumed by circuits for driving the display panel and dynamic power consumed by pixels included in the display panel. The static and dynamic power consumption may increase depending on configuration of the display device, input frame data, etc. Further, occupation area for driving the display panel may increase as the size and the resolution of the display panel increase.
Some example embodiments may provide display panels capable of reducing power consumption.
Some example embodiments may provide display devices including display panels capable of reducing power consumption.
Some example embodiments may provide methods of operating display devices capable of reducing power consumption.
According to an example embodiment, a displace device includes a display panel including a plurality of gate lines, a plurality of data lines and a plurality of sub pixels connected to the plurality of gate lines and the plurality of data lines, respectively, the display panel having a zigzag connection structure in which RG sub pixel pairs included in a first odd-numbered row and RG sub pixel pairs included in a first even-numbered row adjacent to the first odd-numbered row are alternately connected to a first common gate line in a row direction, and BG sub pixel pairs included in a second odd-numbered row and BG sub pixel pairs included in a second even-numbered row adjacent to the second odd-numbered row are alternately connected to a second common gate line in the row direction, and a driving circuit configured to drive the display panel.
According to an example embodiments, a display panel includes a plurality of gate lines extending in a row direction, a plurality of data lines extending in a column direction, a plurality of sub pixels connected to the plurality of gate lines and the plurality of data lines, respectively, in a zigzag connection structure such that RG sub pixel pairs included in a first odd-numbered row and RG sub pixel pairs included in a first even-numbered row adjacent to the first odd-numbered row are alternately connected to a first common gate line, and BG sub pixel pairs included in a second odd-numbered row and BG sub pixel pairs included in a second even-numbered row adjacent to the second odd-numbered row are alternately connected to a second common gate line.
According to an example embodiments, a display panel includes a plurality of gate lines extending in a row direction, a plurality of data lines extending in a column direction, and a plurality of sub pixels connected to the plurality of gate lines and the plurality of data lines, respectively, the plurality of sub pixels having a zigzag connection structure in which (1) a plurality of RG sub pixel pairs and a plurality of BG sub pixel pairs are alternately arranged both in a row direction and in a column direction, and (2) the plurality of RG sub pixel pairs included in a first row and the plurality of RG sub pixel pairs included in a second row immediately adjacent to the first row are connected to a first common gate line, and the plurality of BG sub pixel pairs included in a second row and the plurality of BG sub pixel pairs included in a third row immediately adjacent to the second row are connected to a second common gate line.
In a method of operating a display device according to some example embodiments of the present disclosure, an operation mode of a display device having a zigzag connection structure may include a normal operation mode and an interlace operation mode. In the normal operation mode, all of RG sub pixel pairs and BG sub pixel pairs may be driven during each frame period. In the interlace operation mode, one of the RG sub pixel pairs or the BG sub pixel pairs may be driven during one frame period of two adjacent frame periods and the other one of the RG sub pixel pairs or the BG sub pixel pairs may be driven during the other frame period of the two adjacent frame periods.
The display panel and the display device including the display panel according to some example embodiments of the present disclosure may reduce line flickering in a row direction and/or image degradation by interlace scanning through the zigzag connection structure in which sub pixels of the same color included in two adjacent rows are connected to the same gate line.
Further, the display panel and the display device including the display panel according to some example embodiments of the present disclosure may perform an interlace operation and reduce dynamic power consumption through the zigzag connection structure.
Further, the display panel and the display device including the display panel according to some example embodiments of the present disclosure may reduce occupation area of the gamma voltage generation circuit and reduce static power consumption through the zigzag connection structure.
Example embodiments of the present disclosure will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings.
Various example embodiments will be described more fully hereinafter with reference to the accompanying drawings, in which some example embodiments are shown. In the drawings, like numerals refer to like elements throughout. The repeated descriptions may be omitted.
In this disclosure, a zigzag connection structure ZZST may include a structure in which sub pixels of a particular color are connected to ones of odd-numbered gate lines or even-numbered gate lines) and sub pixels of another color are connected to the other ones of even-numbered gate lines or odd-numbered gate lines.
Referring to
A pixel or a pixel cluster may include a plurality of sub pixels of different colors. For example, one pixel may be a combination of at least two pixels among a R (red) sub pixel, a G (green) sub pixel, a B (blue) sub pixel, a W (white) sub pixel, etc.
As illustrated in
In some example embodiments, the display panel may have a zigzag connection structure in which RG sub pixel pairs included in an odd-numbered row of two adjacent rows and RG sub pixel pairs included in an even-numbered row of the two adjacent rows are alternately connected to a common gate line, and BG sub pixel pairs included in an odd-numbered row of two adjacent rows and BG sub pixel pairs included in an even-numbered row of the two adjacent rows are alternately connected to a common gate line, as illustrated in
As described below, through such zigzag connection structure ZZST, line flickering in the row direction DR1 and image degradation by interlace scanning may be reduced. Also an interlace operation may be performed more efficiently, and dynamic power consumption may be reduced through the zigzag connection structure ZZST. Further occupation area of a gamma voltage generation circuit may be reduced and static power consumption may be reduced through the zigzag connection structure ZZST.
Referring to
The display panel 110 includes a plurality of gate lines GL1˜GLm extending in a row direction DR1, a plurality of data lines DL1˜DLn extending in a column direction DR2 perpendicular to the row direction DR1, and a plurality of sub pixels coupled to the plurality of data lines DL1˜DLn and the plurality of gate lines GL1˜GLm, respectively. For example, the plurality sub pixels may be arranged in a matrix form of m rows and n columns.
In some example embodiments, the display panel 110 in
Referring to
The structure of the sub pixel Spa of
In some example embodiments, the display panel 110 in
Referring to
The structure of the sub pixel SPb of
Referring back to
The data driver circuit 130 provides data signals to display panel 110 by providing data voltages through the data lines DL1˜DLn. The gate driver circuit 140 provides gate driving signals through the gate lines GL1˜GLm for controlling rows of sub pixels. The timing controller 120 controls overall operations of the display device 100. The timing controller 120 may provide control signals CONT1 and CONT2 to control the gate driver circuit 140 and the data driver circuit 130, respectively, to control the display panel 110. In an example embodiment, the timing controller 120, the data driver circuit 130 and the gate driver circuit 140 may be implemented as a single integrated circuit (IC). In another example embodiment, the timing controller 120, the data driver circuit 130 and the gate driver circuit 140 may be implemented as two or more ICs.
The gamma voltage generation circuit 150 generates gamma voltages VGREF and provides the gamma voltages VGREF to the data driver circuit 130. The gamma voltages VGREF have voltage levels corresponding to the display data DATA. For example, the gamma voltage generation circuit 150 may include a resistor string circuit such that a plurality of resistors are coupled in series between a power supply voltage and a ground voltage to provide divided voltages as the gamma voltages VGREF. In an example embodiment, the gamma voltage generation circuit 150 may be included in the data driver circuit 130. As described below, the gamma voltage generation circuit 150 may generate gamma voltages VGREF corresponding to respective colors.
The display panel 110 has a zigzag connection structure according to some example embodiments. Further, the timing controller 120, the data driver circuit 130, the gate driver circuit 140 and the gamma voltage generation circuit 150 may have configuration for driving the display panel of the zigzag connection structure as will be described below.
For example, the zigzag connection structure ZZSTa of a display panel refers to a connection structure in which (1) a plurality of RG sub pixel pairs and a plurality of BG sub pixel pairs are alternately arranged both in a row direction and in a column direction, and (2) the RG sub pixels included in a first row and the RG sub pixel pairs included in a second row immediately adjacent to the first row are connected to a first common gate line, and the BG sub pixel pairs included in a second row and the BG sub pixel pairs included in a third row immediately adjacent to the second row are connected to a second common gate line. Referring to
Each of the RG sub pixel pairs RGP1˜RGP4 includes one R sub pixel and one G sub pixel adjacent in the row direction DR1. For example, the first RG sub pixel pair RGP1 includes the R sub pixel R11 and the G sub pixel G12 in the first row RW1, the second RG sub pixel pair RGP2 includes the R sub pixel R23 and the G sub pixel G24 in the second row RW2, the third RG sub pixel pair RGP3 includes the R sub pixel R31 and the G sub pixel G32 in the third row RW3, and the fourth RG sub pixel pair RGP4 includes the R sub pixel R43 and the G sub pixel G44 in the fourth row RW4.
Each of the BG sub pixel pairs BGP1˜BGP4 includes one B sub pixel and one G sub pixel adjacent in the row direction DR1. For example, the first BG sub pixel pair BGP1 includes the B sub pixel B13 and the G sub pixel G14 in the first row RW1, the second BG sub pixel pair RGP2 includes the B sub pixel R21 and the G sub pixel G22 in the second row RW2, the third BG sub pixel pair BGP3 includes the B sub pixel B33 and the G sub pixel G34 in the third row RW3, and the fourth BG sub pixel pair BGP4 includes the B sub pixel B41 and the G sub pixel G42 in the fourth row RW4.
The RG sub pixel pairs RGP1˜RGP4 and the BG sub pixel pairs BGP1˜BGP4 are alternately arranged in the row direction DR1 and the column direction DR2.
As a result, in the zigzag connection structure ZZSTa, the RG sub pixel pairs included in an odd-numbered row of two adjacent rows and the RG sub pixel pairs included in an even-numbered row of the two adjacent rows are alternately connected to a common gate line, and BG sub pixel pairs included in an odd-numbered row of two adjacent rows and BG sub pixel pairs included in an even-numbered row of the two adjacent rows are alternately connected to a common gate line.
For example, as illustrated in
As described below, through such zigzag connection structure ZZSTa, line flickering in the row direction DR1 and image degradation by interlace scanning may be reduced. Also an interlace operation may be performed more efficiently and dynamic power consumption may be reduced through the zigzag connection structure ZZST. Further occupation area of a gamma voltage generation circuit may be reduced and static power consumption may be reduced through the zigzag connection structure ZZST.
Referring to
Each of the data drivers DR is connected to each of the data lines DL1˜DL8. The half line buffer circuit may include a plurality of unit buffers BF. The unit buffers BF may delay and output data corresponding to a half of the plurality of data lines DL1˜DL8 by one horizontal period. Accordingly the number of the unit buffers is K when the number of the data lines 2K.
In case of the zigzag connection structure ZZSTa of
When the gate lines GL1˜GL5 are enabled sequentially from the first gate line GL1 to the fifth gate line GL5 by the interval of the horizontal period, the sub pixel pairs RGP1, RGP2, RGP3 and BGP4 connected to the first and second data lines DL1 and DL2 are driven to be delayed by the horizontal period with respect to the sub pixel pairs BGP1, RGP2, BGP3 and RGP4 connected to the third and fourth data lines DL3 and DL4 Thus, the sub pixel pairs connected to the (4K−3)-th data line (K is a positive integer) and (4K−2)-th data line are driven to be delayed by the horizontal period with respect to the sub pixel pairs connected to the (4K−1)-th data line and the 4K-th data line.
The data driver 131 receives data bits DB1˜DB8 corresponding to the same row in synchronization with the same horizontal period, and the half line buffer circuit 200 delay the corresponding data bits DB1, DB2 DB5 and DB6 by one horizontal period to output the delayed data bits DB1′, DB2′, DB5′ and DB6′. As a result, the data driver circuit 131 including the half line buffer circuit 200 of
Referring to
The data driver circuit 131 receives first gamma voltages VGREF1 and second. gamma voltages VGREF2 from the gamma voltage generation circuit 150 in
For example, in case of
During the first horizontal period HP1, the first gate driving signal GS1 on the first gate line GL1 is activated to drive the sub pixels B13 and G14 or the sub pixel pair BGP1 that are connected to the enabled first gate line GL1. The B sub pixels and the G sub pixels are driven during the first horizontal period HP1, and thus the first gamma voltages VGREF1 correspond to the B sub pixels and the second gamma voltages VGREF2 correspond to the G sub pixels.
During the second horizontal period HP2, the second gate driving signal GS2 on the second gate line GL2 is activated to drive the sub pixels R11, G12, R23 and G24 or the sub pixel pairs RGP1 and RGP2 that are connected to the enabled second gate line GL2. The R sub pixels and the G sub pixels are driven during the second horizontal period HP2, and thus the first gamma voltages VGREF1 correspond to the R sub pixels and the second gamma voltages VGREF2 correspond to the G sub pixels.
During the third horizontal period HP3, the third gate driving signal GS3 on the third gate line GL3 is activated to drive the sub pixels B21, G22, B33, and G34 or the sub pixel pair BGP2 and BGP3 that are connected to the enabled third gate line GL3. The B sub pixels and the G sub pixels are driven during the third horizontal period HP3, and thus the first gamma voltages VGREF1 correspond to the B sub pixels and the second gamma voltages VGREF2 correspond to the G sub pixels.
During the fourth horizontal period HP4, the fourth gate driving signal GS4 on the fourth gate line GL4 is activated to drive the sub pixels R31, G32, R43, and G44 or the sub pixel pairs RGP3 and RGP4 that are connected to the enabled fourth gate line GL4. The R sub pixels and the G sub pixels are driven during the fourth horizontal period HP4, and thus the first gamma voltages VGREF1 correspond to the R sub pixels and the second gamma voltages VGREF2 correspond to the G sub pixels.
As such, all of the gate lines are driven sequentially during each frame period FP in the normal operation mode, and thus the BG sub pixel pairs and the RG sub pixel pairs may be alternately driven per horizontal period.
Line flickering along the row direction DR1 may be reduced because the sub pixel pairs forming the zigzag pattern in the two adjacent rows are driven during each horizontal period. Further, as will be described with reference to
As illustrated in
As such, only the RG sub pixel pairs or only the BG sub pixel pairs may be driven during each horizontal period in the normal operation mode through the zigzag connection structure ZZSTa according to some example embodiments. Thus, the line flickering in the row direction may be reduced, the occupation area of the gamma voltage generation circuit may be reduced and the static power consumption may be reduced.
Referring to
Each of the RG sub pixel pairs RGP1˜RGP4 includes one R sub pixel and one G sub pixel adjacent in the row direction DR1. For example, the first RG sub pixel pair RGP1 includes the R sub pixel R11 and the G sub pixel G12 in the first row RW1, the second RG sub pixel pair RGP2 includes the G sub pixel G23 and the R sub pixel R24 in the second row RW2, the third RG sub pixel pair RGP3 includes the R sub pixel R31 and the G sub pixel G32 in the third row RW3, and the fourth RG sub pixel pair RGP4 includes the G sub pixel G43 and the R sub pixel R44 in the fourth row RW4. The positions of the R sub pixel and the G sub pixel of the second RG sub pixel pair RGP2 and the fourth RG sub pixel pair RGP4 in the zigzag connection structure ZZSTb of
Each of the BG sub pixel pairs BGP1˜BGP4 includes one B sub pixel and one G sub pixel adjacent in the row direction DR1. For example, the first BG sub pixel pair BGP1 includes the B sub pixel B13 and the G sub pixel G14 in the first row RW1, the second BG sub pixel pair BGP2 includes the G sub pixel G21 and the B sub pixel B22 in the second row RW2, the third BG sub pixel pair BGP3 includes the B sub pixel B33 and the G sub pixel G34 in the third row RW3, and the fourth BG sub pixel pair BGP4 includes the G sub pixel G41 and the 13 sub pixel B42 in the fourth row RW4. The positions of the B sub pixel and the G sub pixel of the second BG sub pixel pair BGP2 and the fourth BG sub pixel pair BGP4 in the zigzag connection structure ZZSTb of
The RG sub pixel pairs RGP1˜RGP4 and the BG sub pixel pairs BGP1˜BGP4 are alternately arranged in the row direction DR1 and the column direction DR2.
As a result, in the zigzag connection structure ZZSTb, the RG sub pixel pairs included in an odd-numbered row of two adjacent rows and the RG sub pixel pairs included in an even-numbered row of the two adjacent rows are alternately connected to a common gate line, and BG sub pixel pairs included in an odd-numbered row of two adjacent rows and BG sub pixel pairs included in an even-numbered row of the two adjacent rows are alternately connected to a common gate line.
For example, as illustrated in
Through such zigzag connection structure ZZSTb, line flickering in the row direction DR1 and image degradation by interlace scanning may be reduced. Also an interlace operation may be performed more efficiently and dynamic power consumption may be reduced through the zigzag connection structure ZZST. Further occupation area of a gamma voltage generation circuit may he reduced and static power consumption may be reduced through the zigzag connection structure ZZST.
Referring to
Each of the data drivers DR is assigned to two adjacent data lines. For example, one data driver DR is assigned to the first and second data lines DL1 and DL2, and another data driver DR is assigned to the third and fourth data lines DL3 and DL4.
The switch circuit 300 may selectively connect each of the data drivers DR to one of the two adjacent data lines. For example, the switch circuit 300 may include first switching elements T11 and T12 that are turned on in response to a first switch signal SW1 and second switching elements T21 and T22 that are turned on in response to a second switch signal SW2. The first switch signal SW1 and the second switch signal SW2 may be included in the timing control signal CONT2 provided from the timing controller 120 in
In case of the zigzag connection structure ZZSTa of FIG, 4 or the zigzag connection structure ZZSTb of
When the gate lines GL1˜GL5 are enabled sequentially from the first gate line GL1 to the fifth gate line GL5 by the interval of the horizontal period, the first switch signal SW1 and the second switch signal SW2 may be activated sequentially during the each horizontal period. As a result, all of the 2K data lines (K is a positive integer) may be driven during each horizontal period using K data drivers.
Referring to
The data driver circuit 133 receives gamma voltages VGREF from the gamma voltage generation circuit 150 in
For example, in configuration of
Comparing
During the first and second horizontal periods HP1 and HP2, the first gate driving signal GS1 on the first gate line GL1 is activated, and the first and second signals SW1 and SW2 are sequentially activated to drive the sub pixels B13 and G14 or the sub pixel pair BGP1 that are connected to the enabled first gate line GL1. The B sub pixels and the G sub pixels are sequentially driven during the first and second horizontal periods HP1 and HP2, and thus the gamma voltages VGREF are switched between the gamma voltages corresponding to the B sub pixels and the gamma voltages corresponding to the G sub pixels.
During the third and fourth horizontal period HP3 and HP4, the third gate driving signal GS3 on the third gate line GL3 is activated and the first and second signals SW1 and SW2 are sequentially activated to drive the sub pixels B21, G22, B33 and G34 or the sub pixel pair BGP2 and BGP3 that are connected to the enabled third gate line GL3. In the same way as the first and second horizontal periods HP1 and HP2, the B sub pixels and the G sub pixels are sequentially driven during the third and fourth horizontal periods HP3 and HP4, and thus the gamma voltages VGREF are switched between the gamma voltages corresponding to the B sub pixels and the gamma voltages corresponding to the G sub pixels. Although not illustrated in
As such, only the odd-numbered gate lines are driven sequentially and the even-numbered gate lines are disabled during the N-th frame period FP(N) in the interlace operation mode, and thus only the BG sub pixel pairs are driven with new data bits and the RG sub pixel pairs maintains the previous states during the N-th frame period FP(N).
As illustrated in
Referring to
The data driver circuit 133 receives gamma voltages VGREF from the gamma voltage generation circuit 150 in
For example, in configuration of
Comparing
During the first and second horizontal periods HP1 and HP2, the second gate driving signal GS2 on the second gate line GL2 is activated and the first and second signals SW1 and SW2 are sequentially activated to drive the sub pixels R11, G12, R23 and G24 or the sub pixel pairs RGP1 and RGP2 that are connected to the enabled second gate line GL2. The R sub pixels and the G sub pixels are sequentially driven during the first and second horizontal periods HP1 and HP2, and thus the gamma voltages VGREF are switched between the gamma voltages corresponding to the R sub pixels and the gamma voltages corresponding to the G sub pixels.
During the third and fourth horizontal period HP3 and HP4, the fourth gate driving signal GS4 on the fourth gate line GL4 is activated and the first and second signals SW1 and SW2 are sequentially activated to drive the sub pixels R31, G32, R43 and G44 or the sub pixel pair RGP3 and RGP4 that are connected to the enabled fourth gate line GL4. In the same way as the first and second horizontal periods HP1 and HP2, the R sub pixels and the G sub pixels are sequentially driven during the third and fourth horizontal periods HP3 and HP4, and thus the gamma voltages VGREF are switched between the gamma voltages corresponding to the R sub pixels and the ma voltages corresponding to the G sub pixels. Although not illustrated in
As such, only the even-numbered gate lines are driven sequentially and the odd-numbered gate lines are disabled during the (N+1)-th frame period FP(N+1) in the interlace operation mode, and thus only the RG sub pixel pairs are driven with new data bits and the BG sub pixel pairs maintains the previous states during the (N+1)-th frame period FP(N+1).
As illustrated in
As such, in the interlace operation mode of the zigzag connection structure ZZSTa according to some example embodiments, line flickering along the row direction DR1 may be reduced because the sub pixel pairs forming the zigzag pattern in the two adjacent rows are driven during each horizontal period. Further, as will be described with reference to
As such, in the interlace operation mode as described with reference to
Referring to
Each of the data drivers DR1˜DR4 is assigned to each of the data lines DL1˜DL4. The switch circuit 400 controls connections between each data driver and each data line and connections between two adjacent odd-numbered and even-numbered data lines.
For example, the switch circuit 400 may include first switching elements T11 and T12 that are turned on in response to a first switch signal SW1, second switching elements T21 and T22 that are turned on in response to a second switch signal SW2, and third switching elements T31 and T32 that are turned on in response to a third switch signal SW3. The first switch signal SW1, the second switch signal SW2 and the third switch signal SW3 may be included in the timing control signal CONT2 provided from the timing controller 120 in
Using the switch circuit 400 of
Referring to FIG, 16, a gamma voltage generation circuit 150a includes a first gamma voltage generator (VLT1) 151, a second gamma voltage generator (VLT2) 152 and a third gamma voltage generator (VLT3) 153. The first gamma voltage generator 151 generates gamma voltages VGREF(R) corresponding to the R sub pixels, the second gamma voltage generator 152 generates gamma voltages VGREF(G) corresponding to the G sub pixels and the third gamma voltage generator 153 generates gamma voltages VGREF(B) corresponding to the B sub pixels.
If the R, G and B sub pixels are connected to the same gate line and each data driver is connected to each data line as illustrated in
A gamma voltage generation circuit 150b of
Referring to
As described with reference to
As such, the display panel and the display device including the display panel according to some example embodiments may reduce occupation area of the gamma voltage generation circuit and reduce static power consumption through the zigzag connection structure.
A gamma voltage generation circuit 150c of
Referring to
As described with reference to
As such, the display panel and the display device including the display panel according to some example embodiments may further reduce occupation area of the gamma voltage generation circuit and further reduce static power consumption through the zigzag connection structure and the interlace operation.
Referring to
For example, the normal operation mode may be selected when a video of high quality is displayed and the interlace operation mode may be selected when a video requiring low quality or a still image is displayed. In some example embodiments, the display device may have a flexible configuration to select and perform the normal operation mode or the interlace operation mode through the zigzag connection structure. In other example embodiments, the display device may have a fixed configuration to perform the normal operation mode or the interlace operation mode through the zigzag connection structure.
Referring to
The processor 710 may perform various computing functions or tasks. The processor 710 may be any processing unit such as a microprocessor or a central processing unit (CPU). The processor 710 may be connected to other components via an address bus, a control bus, a data bus, or the like. Further, the processor 710 may be coupled to an extended bus such as a peripheral component interconnection (PCI) bus.
The memory device 720 may store data for operations of the mobile device 700. For example, the memory device 720 may include at least one non-volatile memory device such as an erasable programmable read-only memory (EPROM) device, an electrically erasable programmable read-only memory (EEPROM) device, a flash memory device, a phase change random access memory (PRAM) device, a resistance random access memory (RRAM) device, a nano-floating gate memory (NFGM) device, a polymer random access memory (PoRAM) device, a magnetic random access memory (MRAM) device, a ferroelectric random access memory (FRAM) device, and/or at least one volatile memory device such as a dynamic random access memory (DRAM) device, a static random access memory (SRAM) device, a mobile dynamic random access memory (mobile DRAM) device, etc.
The storage device 730 may be, for example, a solid state drive (SSD) device, a hard disk drive (HDD) device, a CD-ROM device, etc. The I/O device 740 may be, for example, an input device such as a keyboard, a keypad, a mouse, a touch screen, and/or an output device such as a printer, a speaker, etc. The power supply 750 may supply power for operating the mobile device 700. The display device 760 may communicate with other components via the buses or other communication links.
As described above with reference to
As described above, the display panel and the display device including the display panel according to some example embodiments may reduce line flickering in a row direction and image degradation by interlace scanning through the zigzag connection structure in which sub pixels of the same color included in two adjacent rows are connected to the same gate line. Further, the display panel and the display device including the display panel according to some example embodiments may perform an interlace operation and reduce dynamic power consumption through the zigzag connection structure. Further, the display panel and the display device including the display panel according to some example embodiments may reduce occupation area of the gamma voltage generation circuit and reduce static power consumption through the zigzag connection structure.
The disclosed example embodiments may be applied to any device or any system including a display panel. For example, the disclosed example embodiments may be applied to a cellular phone, a smart phone, a tablet computer, a personal digital assistant (PDA), a portable multimedia player (PMP), a digital camera, a music player, a portable game console, a navigation system, a video phone, a personal computer (PC), a server computer, a workstation, a tablet computer, a laptop computer, etc.
The foregoing is illustrative of example embodiments and is not to be construed as limiting thereof. Although a few example embodiments have been described, those skilled in the art will readily appreciate that many modifications are possible in the disclosed example embodiments without materially departing from the present inventive concepts.
Number | Date | Country | Kind |
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10-2017-0063947 | May 2017 | KR | national |