Patent ID: 11935469
Assignee: BOE TECHNOLOGY GROUP CO., LTD.
Field: Audio-visual technology (Electrical engineering)
Classification: CPC G | IPC G

Claim 9:
10. A method for driving a display panel, wherein the display panel comprises a gate driving circuit and M pixel circuit arrays, wherein each of the M pixel circuit arrays comprises
a first signal sensing line and a second signal sensing line; and
N pixel circuits arranged in a column,
wherein all of the N pixel circuits are divided into a first group and a second group, each pixel circuit in the first group is coupled to the first signal sensing line, and each pixel circuit in the second group is coupled to the second signal sensing line different from the first signal sensing line, where N is a positive integer greater than 1; and
wherein the first group and the second group are respectively located in a first region and a second region that do not overlap each other, the first signal sensing line extends only through the first region, the second signal sensing line extends only through the second region, and the first signal sensing line and the second signal sensing line are aligned with each other in a column direction of the N pixel circuits,
and the M pixel circuit arrays comprise M columns of pixel circuits and N rows of pixel circuits, M being a positive integer,
wherein the gate driving circuit is configured to: drive the pixel circuits in the second group not to emit light during driving the pixel circuits in the first group to display an image; or drive the pixel circuits in the first group not to emit light during driving the pixel circuits in the second group to display an image;
wherein N is an even number, and the gate driving circuit is configured to: drive the pixel circuits in ((N/2)+1)-th to N-th rows not to emit light during driving the pixel circuits in 1-st to (N/2)-th rows to display the image; or drive the pixel circuits in 1-st to (N/2)-th rows not to emit light during driving the pixel circuits in ((N/2)+1)-th to N-th rows to display the image;
wherein the gate driving circuit comprises N gate driving units cascaded together, the N gate driving units are in one-to-one correspondence with the N rows of pixel circuits, and the N gate driving units are coupled to the N rows of pixel circuits, respectively;
wherein the control electrodes of the display switching transistors of the pixel circuits in a same row of the N rows of pixel circuits are all coupled to a same first gate line, and the control electrodes of the sensing switching transistors of the pixel circuits in a same row of the N rows of pixel circuits are all coupled to a same second gate line;
wherein each of the N gate driving units comprises a signal input terminal, a cascade output terminal, a first signal output terminal, and a second signal output terminal; and
the signal input terminal of each of the gate driving unit in a first stage and the gate driving unit in a second stage is coupled to a frame start signal input line, the signal input terminal of the gate driving unit in an i-th stage is coupled to the cascade output terminal of the gate driving unit in an (i−2)-th stage, and the first signal output terminal and the second signal output terminal of each of the N gate driving units are coupled to the first gate line and the second gate line of each pixel circuit in a corresponding row, where 3≤i≤N; and
the 1-st to (N/2)-th rows of pixel circuits of the N rows of pixel circuits are located in an upper half screen, the ((N/2)+1)-th to N-th rows of pixel circuits of the N rows of pixel circuits are located in a lower half screen, and the method comprises:
providing a turn-on level to the first gate line and the second gate line of each row of pixel circuits in one of the upper half screen and the lower half screen, respectively, to turn on both the display switching transistor and the sensing switching transistor, so as to input a data voltage provided by the data line to the control electrode of the driving transistor via the display switching transistor, and to input a low level provided by a corresponding one of the first signal sensing line and the second signal sensing line to the second electrode of the driving transistor;
providing a turn-off level to the first gate line and the second gate line of each row of pixel circuits in the one of the upper half screen and the lower half screen, respectively, to turn off both the display switching transistor and the sensing switching transistor, thereby causing the organic light emitting diode to start light emission; and
during providing the turn-on level to the first gate line and the second gate line of each row of pixel circuits in the one of the upper half screen and the lower half screen, respectively, providing a turn-on level to the first gate line and the second gate line of each row of pixel circuits in the other of the upper half screen and the lower half screen, respectively, to allow the data voltage provided by the data line to be input to the control electrode of the driving transistor via the display switching transistor, and allow a reference voltage provided by a corresponding one of the first and second signal sensing lines to be input to the second electrode of the driving transistor, wherein the reference voltage is higher than the data voltage to make the organic light emitting diodes of a respective row of pixel circuits in the other of the upper half screen and the lower half screen not emit light.