Abstract: The present invention relates to an OLED pixel compensation circuit for removing a substrate effect. The pixel compensation circuit according to the present invention uses six transistors and two storage batteries to fix both a source voltage and a body voltage of a driving transistor that drives an OLED, thereby having the effects of eliminating errors due to a substrate effect and presenting more accurate pixel compensation results.

Abstract: According to an embodiment of the present invention, an apparatus for detecting a fingerprint is provided, which includes a plurality of sensor pads receiving a response signal from a finger applied to a driving signal, a sensing circuit outputting a sensing signal based on the response signal, and a sensing signal adjusting unit sampling the sensing signal outputted from the sensing circuit maintaining the sensing signal, and adjusting an average voltage level of the sensing signal based on a reference voltage.

Abstract: According to an embodiment of the present invention, an apparatus for detecting a fingerprint is provided, which includes a plurality of sensor pads receiving a response signal from a finger applied to a driving signal, a sensing circuit outputting a sensing signal based on the response signal, and a sensing signal adjusting unit sampling the sensing signal outputted from the sensing circuit maintaining the sensing signal, and adjusting an average voltage level of the sensing signal based on a reference voltage

Abstract: Provided is a circuit driving method which can minimize a problem generated by a peak current in a display memory device. Data to be transferred to a display panel is read out from a memory cell array storing binary information. The read-out data are stored in source data buffers and a plurality of source data buffers are divided into several groups and then enabled. An enable signal for each group is derived from a single enable signal and has a different delay time. In the source data buffers delayed by each group and enabled, consumption of current is distributed so that a peak current flowing in the overall source data buffer is lowered. Thus, reliability in the operation of a circuit is improved and the operation speed increases.

Abstract: There is provided a driving circuit using an internal diode instead of a zener diode and a discharging method using the same capable of replacing a driving circuit including an external zener diode, thereby reducing costs. The driving circuit using a discharging method for driving an OLED (organic light emitting diode) panel, the driving circuit includes: a precharge channel which is constructed in a current mirror scheme and is turned off when discharging; a discharge channel which is connected to the to precharge channel in series and operates when discharging; and an internal diode which is connected to the discharge channel and controls a discharge voltage level. According to the present invention, a voltage level can be controlled not to be discharged to a ground level by using an internal diode circuit when discharging. Therefore, a driving circuit requiring low power can be implemented, and additional costs are not needed.

Abstract: There is provided a driving circuit in which a voltage level can reach a full Vcc level when precharging and a precharging method using the same although a parasitic capacitance of an organic light emitting diode (OLED) panel increases. A driving circuit of an OLED panel includes according to the present invention: a precharge channel which is applied with Vcc voltage and operates when precharging; a discharge channel which is connected to the precharge channel in series and is connected to ground (GND) and is turned off when precharging; and a time shift circuit which is connected to the precharge channel and controls a voltage level according to a time setting. According to the present invention, a precharge voltage level can reach a full Vcc level according to a time setting although a parasitic capacitance of an OLED panel increases. Therefore, a driving circuit can be simply and easily implemented.

Abstract: Provided is a circuit driving method which can minimize a problem generated by a peak current in a display memory device. Data to be transferred to a display panel is read out from a memory cell array storing binary information. The read-out data are stored in source data buffers and a plurality of source data buffers are divided into several groups and then enabled. An enable signal for each group is derived from a single enable signal and has a different delay time. In the source data buffers delayed by each group and enabled, consumption of current is distributed so that a peak current flowing in the overall source data buffer is lowered. Thus, reliability in the operation of a circuit is improved and the operation speed increases.

Abstract: A multi-port static random access memory for reducing an occupation area of a layout memory cells on a substrate having the improvements from a first plurality of metal electrode layers on a first plurality of active regions included in one unit cell and in other unit cell neighbored to the corresponding one unit cell of the first plurality of metal electrode layers being commonly connected to the power supply source, comprises: a second plurality of the metal electrode layers on second plurality of the active regions and to be independently and separately connected to the power supply source, by every one unit cell in cell array.

Abstract: A multi-port static random access memory for reducing an occpation area of a layout memory cells on a substrate having the improvements from a first plurality of metal electrode layers on a first plurality of active regions included in one unit cell and in other unit cell neighbored to the corresponding one unit cell of the first plurality of metal electrode layers being commonly connected to the power supply source, comprises: a second plurality of the metal electrode layers on second plurality of the active regions and to be independently and separately connected to the power supply source, by every one unit cell in cell array.

Abstract: A power supply circuit for a static random access memory cell or the like is provided that reliably supplies a voltage different from an external power supply voltage. The power supply circuit can include a first transistor with a first electrode coupled to an external power source, and a second electrode coupled to a first node that supplies the voltage different from the external power supply voltage. First and second resistors are coupled in series between the first node and a ground voltage. A third resistor is coupled in series to the external power supply. A second transistor has a first electrode coupled to the third resistor at a second node, a second electrode coupled to the ground voltage, and a control electrode coupled to a third node, which is between the first and second resistors.