Output buffer circuit and source driving circuit including the same

A source driving circuit includes an output buffer circuit to compensate for slew rate of signals used to drive a display device. The output buffer circuit includes a bias current control signal generating circuit and a channel amplifying circuit. The bias current control signal generating circuit performs an exclusive OR operation on an input signal and an output signal of a reference operational amplifier to generate a bias current control signal. The channel amplifying circuit adjusts the slew rate of a plurality of output voltage signals in response to the bias current control signal. The output signals are then used to control the display device.

CROSS-REFERENCE TO RELATED APPLICATION

Korean Patent Application No. 10-2013-0023462, filed on Mar. 5, 2013, and entitled, “Output Buffer Circuit and Source Driving Circuit Including the Same,” is incorporated by reference herein in its entirety.

BACKGROUND

One or more embodiments described herein relate to a display device.

2. Description of Related Art

Flat panel devices are widely used as display devices. Each flat panel device generally includes a display panel, a control unit, a gate driver, and a source driver. The source driver drives the data lines of the display panel using voltages corresponding to data signals received from the control unit. In one type of device, the source driver receives a plurality of gray voltages output from a gray voltage generating unit, and selects one of the plurality of gray voltages to drive the data line.

SUMMARY

In accordance with one embodiment, an output buffer circuit includes a bias current control signal generating circuit including a reference operational amplifier, the bias current control signal generating circuit configured to perform an exclusive OR operation on an input signal and an output signal of the reference operational amplifier to generate a bias current control signal; and a channel amplifying circuit configured to adjust a slew rate of a plurality of output voltage signals in response to the bias current control signal, the channel amplifying circuit configured to perform buffering on a plurality of input voltage signals to generate the plurality of output voltage signals.

The output buffer circuit may be configured to further adjust the slew rate of the plurality of output voltage signals in response to a gray code of a source driving circuit of a display device. A magnitude of a tail current of the plurality of output voltage signals may be configured to be adjusted according to a combination of bits of the gray code. The slew rate may increases with an increase in the tail current.

The bias current control signal generating circuit may include an XOR circuit that performs the exclusive OR operation on the input signal and the output signal of the reference operational amplifier to generate the bias current control signal. The bias current control signal may be configured to be activated during a transition period, in which the output signal of the reference operational amplifier changes from a minimum value to half of a maximum value. Also, the bias current control signal may be configured to be activated during a transition period, in which the output signal of the reference operational amplifier changes from a ground voltage to half of a supply voltage.

The bias current control signal generating circuit may include a first reference operational amplifier configured to buffer a first reference input signal to generate a first reference output signal; a first XOR circuit configured to perform the exclusive OR operation on the first reference input signal and the first reference output signal; an inverter configured to invert a phase of the first reference input signal; a second reference operational amplifier configured to buffer an output signal of the inverter to generate a second reference output signal; a second XOR circuit configured to perform the exclusive OR operation on the output signal of the inverter and the second reference output signal; and an OR circuit configured to perform an OR operation on an output signal of the first XOR circuit and an output signal of the second XOR circuit to generate the bias current control signal.

The first reference operational amplifier and the second reference operational amplifier may be configured to have one or more electrical characteristics that are substantially equal. Additionally, or alternatively, the bias current control signal may be configured to be activated during a pulse duration time of a signal with a wider pulse width of the output signal of the first XOR circuit and the output signal of the second XOR circuit.

The bias current control signal is configured to be activated during a longer period of: a first transition period in which the output signal of the first reference operational amplifier changes from a minimum value to half of a maximum value, or a second transition period in which the output signal of the second reference operational amplifier changes from the maximum value to half of the maximum value.

The bias current control signal may be configured to be activated during a longer period of: a first transition period in which the output signal of the first reference operational amplifier increases from a ground voltage to half of a supply voltage, or a second transition period in which the output signal of the second reference operational amplifier decreases from the supply voltage to half of the supply voltage.

The channel amplifying circuit may include a plurality of channel amplifiers configured to generate the plurality of output voltage signals, wherein each of the channel amplifiers may include a differential input unit configured to include a P-type differential input unit and an N-type differential input unit, and receive an input voltage signal and an output voltage signal in a differential mode; an upper bias unit electrically connected to the P-type differential input unit, and configured to connect the P-type differential input unit to a supply voltage and to adjust a magnitude of a bias current supplied to the P-type differential input unit in response to the bias current control signal; a lower bias unit electrically connected to the N-type differential input unit, and configured to connect the N-type differential input unit to a ground voltage and to adjust a magnitude of a bias current supplied to the N-type differential input unit in response to the bias current control signal; a load stage electrically connected to the differential input unit, and configured to operate as a load of the differential input unit; and an output stage electrically connected to the load stage, and configured to connect an output terminal of the load stage to the supply voltage or the ground.

The reference operational amplifier and the channel amplifiers may be configured to have one or more electric characteristics that are substantially equal. The upper bias unit may include a first PMOS transistor configured to have a source connected to the supply voltage, a gate to which a first bias voltage is applied, and a drain connected to the P-type differential input unit; a second PMOS transistor configured to have a source connected to the supply voltage, and a gate to which the first bias voltage is applied; and a switch configured to be coupled between a drain of the second PMOS transistor and the P-type differential input unit, and turned on or off in response to the bias current control signal. A size of the second PMOS transistor may be substantially half that of the first PMOS transistor.

The lower bias unit may include a first NMOS transistor configured to have a source connected to the ground voltage, a gate to which a second bias voltage is applied, and a drain connected to the N-type differential input unit; a second NMOS transistor configured to have a source connected to the ground voltage, and a gate to which the second bias voltage is applied; and a switch configured to be coupled between a drain of the second NMOS transistor and the N-type differential input unit, and turned on or off in response to the bias current control signal. A size of the second NMOS transistor may be substantially half of that of the first NMOS transistor.

The upper bias unit may include a first PMOS transistor configured to have a source connected to the supply voltage, a gate to which a first bias voltage is applied, and a drain connected to the P-type differential input unit; a second PMOS transistor configured to have a source connected to the supply voltage, and a gate to which the first bias voltage is applied; a third PMOS transistor configured to have a source connected to the supply voltage, and a gate to which the first bias voltage is applied; a fourth PMOS transistor configured to have a source connected to the supply voltage, and a gate to which the first bias voltage is applied; a first switch configured to be coupled between a drain of the second PMOS transistor and the P-type differential input unit, and turned on or off in response to the bias current control signal; a second switch configured to be coupled between a drain of the third PMOS transistor and the P-type differential input unit, and turned on or off in response to a first bit of a gray code; and a third switch configured to be coupled between a drain of the fourth PMOS transistor and the P-type differential input unit, and turned on or off in response to a second bit of the gray code.

A size of the second PMOS transistor may be about half of that of the first PMOS transistor, a size of the third PMOS transistor may be about one fourth of that of the first PMOS transistor, and a size of the fourth PMOS transistor may be about one eighth of that of the first PMOS transistor.

The lower bias unit may include a first NMOS transistor configured to have a source connected to the ground voltage, a gate to which a second bias voltage is applied, and a drain connected to the N-type differential input unit; a second NMOS transistor configured to have a source connected to the ground voltage, and a gate to which the second bias voltage is applied; a third NMOS transistor configured to have a source connected to the ground voltage, and a gate to which the second bias voltage is applied; a fourth NMOS transistor configured to have a source connected to the ground voltage, and a gate to which the second bias voltage is applied; a first switch configured to be coupled between a drain of the second NMOS transistor and the N-type differential input unit, and turned on or off in response to the bias current control signal; a second switch configured to be coupled between a drain of the third NMOS transistor and the N-type differential input unit, and turned on or off in response to a first bit of a gray code; and a third switch configured to be coupled between a drain of the fourth NMOS transistor and the N-type differential input unit, and turned on or off in response to a second bit of the gray code.

A size of the second NMOS transistor may be about half of that of the first NMOS transistor, a size of the third NMOS transistor may be about one fourth of that of the first NMOS transistor, and a size of the fourth NMOS transistor may be about one eighth of that of the first NMOS transistor.

In accordance with another embodiment, a source driving circuit of a display device includes a shift register configured to generate a pulse signal based on a clock signal and an input/output control signal; a data latch circuit configured to latch data according to a shift sequence of the shift register and output the data as digital input signals in response to a load signal; and a digital-to-analog converting circuit configured to generate input voltage signals corresponding to the digital input signals using a gray voltage; and an output buffer circuit configured to buffer the input voltage signals to generate source signals, the output buffer circuit comprising: a bias current control signal generating circuit configured to include a reference operational amplifier, the bias current control signal generating circuit configured to perform an exclusive OR operation on an input signal and an output signal of the reference operational amplifier to generate a bias current control signal; and a channel amplifying circuit configured to adjust a slew rate of a plurality of output voltage signals in response to the bias current control signal, the channel amplifying circuit configured to perform buffering on a plurality of input voltage signals to generate the plurality of output voltage signals.

In accordance with another embodiment, a method of operating a source driving circuit of a display device includes generating a pulse signal based on a clock signal and an input/output control signal using a shift register; latching data according to a shift sequence of the shift register and outputting the data as digital input signals in response to a load signal; generating input voltage signals corresponding to the digital input signals using a gray voltage; performing an exclusive OR operation on an input signal and an output signal of a reference operational amplifier to generate a bias current control signal; and adjusting a slew rate of a plurality of source signals in response to the bias current control signal, and performing buffering on the input voltage signals to generate the plurality of source signals. Also, the method may include adjusting the slew rate of the plurality of source signals based on a gray code of the source driving circuit.

In accordance with another embodiment, a circuit includes a controller to generate a control signal based on a first reference signal and a second reference signal; and a signal generator to generate at least one output signal based on the control signal from the controller, wherein the signal generator adjusts a current of an input signal in response to the control signal to change a slew rate of the output signal, wherein the output signal includes information for controlling a display device. The input signal may include a gamma voltage.

The controller may compare the first and second reference signals, and generates the control signal based on the comparison. The signal generator may change the slew rate based on the adjusted current and a gray code of the display device. Additionally, or alternatively, the signal generator may adjust the current of the input signal by adding a bias current to the input signal.

DETAILED DESCRIPTION

FIG. 1illustrates an embodiment of a source driving circuit100which includes a shift register110, a data latch circuit120, a digital-to-analog converter130, and an output buffer circuit140.

The shift register110may generate a pulse signal based on a clock signal CLK and an input/output control signal DIO. The data latch circuit120may receive data DATA and a load signal TP. The data latch circuit120may latch data DATA according to a shift sequence of the shift register110and outputs the data DATA when the load signal TP is applied.

The digital-to-analog converter130may generate input voltage signals VIN1to VINn, which are analog signals, corresponding to output signals D1to Dn of the data latch circuit120using a gray voltage GMA.

The output buffer circuit140may compensate a slew rate and buffers the input voltage signals VIN1to VINn to generate source signals Y1to Yn. The source signals Y1to Yn may be output to each source line according to a sequence of data DATA applied to the data latch circuit120. In accordance with one embodiment, the source driving circuit100may have a structure of an output buffer circuit as described hereinafter.

The output buffer circuit140included in the source driving circuit100may include a bias current control signal generating circuit and a channel amplifying circuit. The bias current control signal generating circuit may include a reference operational amplifier, and perform an exclusive OR operation on an input signal and an output signal of the reference operational amplifier to generate a bias current control signal. The channel amplifying circuit may compensate for a slew rate in response to the bias current control signal, and perform buffering on a plurality of input voltage signals to generate a plurality of output voltage signals. The output buffer circuit may further compensate for the slew rate in response to a gray code of a source driving circuit of a display device. A magnitude of a tail current of the plurality of output signals may be adjusted according to a combination of bits of the gray code. The slew rate may increase according to an increase of the tail current. That is, as the magnitude of the tail current of an output signal increases, a transition time of the output voltage signal becomes shorter.

FIG. 2illustrates an embodiment of the digital-to-analog converter130in the source driving circuit ofFIG. 1. Referring toFIG. 2, the digital-to-analog converter130may include a resistor string132and a switching circuit134.

The resistor string132may be coupled between a first reference voltage VREF_H and a second reference voltage VREF_L, and may include a plurality of resistors R1to R18serially connected to each other. Nodes coupled to the resistors may output gamma voltages VGMA1to VGMA18. When a digital input signal D1, D2, . . . , and Dn is 18-bit data, the resistor string132may include 18 resistors and may output18gamma voltages VGMA1to VGMA18.

The switching circuit134may output the gamma voltages VGMA1to VGMA18corresponding to the digital input signal D1, D2, . . . , and Dn as input voltage signals VIN1to VINn. While 18 resistors are shown, in other embodiments a different number of resistors may be used and/or a different number of gamma voltages may be generated.

FIG. 3illustrates an embodiment of an output buffer circuit140in the source driving circuit ofFIG. 1. Referring toFIG. 3, the output buffer circuit140may include a bias current control signal generating circuit150and a channel amplifying circuit141.

The bias current control signal generating circuit150may include a reference operational amplifier OP_REF_1, and may perform an exclusive OR operation on an input signal VI_REF and an output signal VO_REF of the reference operational amplifier OP_REF_1. The exclusive OR operation generates a bias current control signal VCON_IB. The channel amplifying circuit141may compensate for a slew rate in response to the bias current control signal VCON_IB, and perform buffering on input voltage signals VIN1to VINn to generate output voltage signals Y1to Yn. The channel amplifying circuit141may include channel amplifiers OP_CH1, OP_CH2and OP_CH3.

More specifically, the bias current control signal generating circuit150may include a reference operational amplifier OP_REF_1and an exclusive OR (XOR) circuit XOR1. The XOR circuit XOR1may perform the exclusive OR operation on the input signal VI_REF and the output signal VO_REF of the reference operational amplifier OP_REF_1to generate the bias current control signal VCON_IB.

The bias current control signal VCON_IB may be activated during a transition period in which the output signal of the reference operational amplifier OP_REF_1changes from a minimum value to half of a maximum value. In one embodiment, the bias current control signal VCON_IB may be activated during a transition period in which the output signal of the reference operational amplifier OP_REF_1changes from a ground voltage to a half of a supply voltage.

FIG. 4illustrates an embodiment of the channel amplifier OP_CH1in the channel amplifying circuit141of the output buffer circuit ofFIG. 3. Referring toFIG. 4, the channel amplifier OP_CH1may include a differential input unit146, an upper bias unit142, a lower bias unit144, a load stage147, and an output stage148.

The differential input unit146may include a P-type differential input unit and an N-type differential input unit, and may receive an input voltage signal VIN and an output voltage signal VOUT in a differential mode. The P-type differential input unit may include PMOS transistors MP1and MP2, and the N-type differential input unit may include NMOS transistors MN1and MN2.

The upper bias unit142may be electrically connected to the P-type differential input unit, connect the P-type differential input unit to a supply voltage VDD, and adjust a magnitude of a bias current supplied to the P-type differential input unit in response to the bias current control signal VCON_IB.

The lower bias unit144may be electrically connected to the N-type differential input unit, connect the N-type differential input unit to a ground voltage, and adjust a magnitude of a bias current supplied to the N-type differential input unit in response to the bias current control signal VCON_IB.

The load stage147may be electrically connected to the differential input unit146, and operate as a load of the differential input unit146. The output stage148may be electrically connected to the load stage147, and connect an output terminal of the load stage147to the supply voltage VDD or the ground. In one embodiment, the reference operational amplifier OP_REF_1and the channel amplifiers OP_CH1, OP_CH2and OP_CH3may have the same electric characteristics.

The upper bias unit142may include a first PMOS transistor MP3, a second PMOS transistor MP4, and a switch SW1. The first PMOS transistor MP3may have a source connected to the supply voltage VDD, a gate to which a first bias voltage VB1is applied, and a drain connected to the P-type differential input unit. The second PMOS transistor MP4may have a source connected to the supply voltage VDD, and a gate to which the first bias voltage VB1is applied. The switch SW1may be coupled between a drain of the second PMOS transistor MP4and the P-type differential input unit, and turned on or off in response to the bias current control signal VCON_IB. The size of the second PMOS transistor may be a half of that of the first PMOS transistor.

The lower bias unit144may include a first NMOS transistor MN3, a second NMOS transistor MN4, and a switch SW2. The first NMOS transistor MN3may have a source connected to the ground voltage, a gate to which a second bias voltage VB2is applied, and a drain connected to the N-type differential input unit. The second NMOS transistor MN4may have a source connected to the ground voltage, and a gate to which the second bias voltage VB2is applied. The switch SW2may be coupled between a drain of the second NMOS transistor MN4and the N-type differential input unit, and turned on or off in response to the bias current control signal VCON_IB. The size of the second NMOS transistor may be a half of that of the first NMOS transistor.

The channel amplifier OP_CH1may compensate for a slew rate of an output voltage by adjusting bias currents supplied to the differential input unit146in response to the bias current control signal VCON_IB. This may be accomplished using bias current adjusting unit143included in the upper bias unit142and bias current adjusting unit145included in the lower bias unit144.

The bias current adjusting unit143may include the second PMOS transistor MP4and the switch SW1. The bias current adjusting unit145may include the second NMOS transistor MN4and the switch SW2. The channel amplifier OP_CH1may supply additional bias current to the differential input unit146during a transition period of an output signal in response to the bias current control signal VCON_IB.

FIG. 5illustrates an embodiment of the reference operational amplifier OP_REF in the bias current control signal generating circuit150of the output buffer circuit ofFIG. 3. Referring toFIG. 5, the reference operational amplifier OP_REF may include a differential input unit156, an upper bias unit152, a lower bias unit154, a load stage157, and an output stage158. The structure of the reference operational amplifier OP_REF ofFIG. 5may be the same as that of the channel amplifier OP_CH1, except for the bias current adjusting units143and145. Therefore, the electric characteristics of the reference operational amplifier OP_REF may be similar to that of the channel amplifier OP_CH1.

FIG. 6illustrates an example of a timing diagram for operation of the bias current control signal generating circuit of the output buffer circuit ofFIG. 3, and FIG.7illustrates an example of a timing diagram illustrating an operation of the channel amplifier of the output buffer circuit ofFIG. 3.

Referring toFIG. 6, when an input signal of the reference operational amplifier OP_REF (that is, a reference input signal VI_REF) changes from a “0” level to a VDD level, an output signal of the reference operational amplifier OP_REF (that is, a reference output signal VO_REF) may change from the “0” level to the VDD level with a certain slew rate. In the output buffer circuit, the bias current control signal VCON_IB, generated by the bias current control signal generating circuit150ofFIG. 3, may be activated during a transition period. The transition period may include a period in which the output signal of the reference operational amplifier OP_REF changes from a minimum value (for example, 0V) to half of a maximum value (for example, VDD). That is, the bias current control signal VCON_IB may have a pulse width PW1, and provide an additional bias current to the channel amplifiers of the channel amplifying circuit141during a period of the pulse width PW1.

Referring toFIG. 7, when the input signal VIN of the channel amplifier changes from a minimum gamma value VGMA1to a maximum gamma value VGMA18, the output signal VOUT of the channel amplifier may transit from the minimum gamma value VGMA1to the maximum gamma value VGMA18with a certain slew rate.

In accordance with one embodiment of the output buffer circuit, during a transition period of the output voltage signal VOUT of the channel amplifier, the bias current control signal VCON_IB generated by the bias current control signal generating circuit150may provide an additional bias current to the channel amplifiers. As a result, the slew rate may be compensated.

Since the output buffer circuit compensates for slew rate, the output buffer circuit may have an increased slew rate and a transition of a voltage level may be accomplished in a shorter time compared with an output buffer circuit without a slew rate compensation. The bias current control signal VCON_IB may be activated during a transition period, in which the output signal of the reference operational amplifier OP_REF changes from a minimum value (for example, 0V) to a half of a maximum value (for example, VDD).

FIG. 8illustrates an embodiment of the bias current control signal generating circuit of the output buffer circuit ofFIG. 3. Referring toFIG. 8, the bias current control signal generating circuit150amay include a first reference operational amplifier OP_REF_1, a first XOR circuit XOR1, an inverter INV1, a second reference operational amplifier OP_REF_2, a second XOR circuit XOR2, and an OR circuit OR1.

The first reference operational amplifier OP_REF_1may buffer a first reference input signal VI_REF to generate a first reference output signal VO_REF_1. The first XOR circuit XOR1may perform the exclusive OR operation on the first reference input signal VI_REF and the first reference output signal VO_REF_1. The inverter INV1may invert a phase of the first reference input signal VI_REF. The second reference operational amplifier OP_REF_2may buffer an output signal of the inverter INV1to generate a second reference output signal VO_REF_2. The second XOR circuit XOR2may perform the exclusive OR operation on the output signal of the inverter INV1and the second reference output signal VO_REF_2. The OR circuit OR1may perform an OR operation on an output signal of the first XOR circuit XOR1and an output signal of the second XOR circuit XOR2to generate the bias current control signal VCON_IB.

FIG. 9illustrates an example of a timing diagram for operation of the bias current control signal generating circuit150a. Referring toFIGS. 8 and 9, the bias current control signal generating circuit150amay perforin an OR operation on an output signal VOEX1of the first XOR circuit XOR1and an output signal VOEX2of the second XOR circuit XOR2to generate the bias current control signal VCON_IB. Therefore, the pulse width of the bias current control signal VCON_IB may be determined by a signal with a wider pulse width of VOEX1which has a pulse width PW1and VOEX2which has a pulse width PW2. The bias current control signal generating circuit150aofFIG. 8may supply an enough additional bias current even when a rising transition time and a falling transition time of the reference output signals VO_REF_1and VO_REF_2are not equal to each other, and then perform a slew rate compensation.

FIG. 10illustrates another embodiment of an output buffer circuit in the source driving circuit ofFIG. 1. Referring toFIG. 10, the output buffer circuit140amay include a bias current control signal generating circuit150aand a channel amplifying circuit141a.

The bias current control signal generating circuit150amay have the same structure as the bias current control signal generating circuit150ofFIG. 3. The channel amplifying circuit141amay compensate for a slew rate in response to the bias current control signal VCON_IB and a gray code, and perform buffering on input voltage signals VIN1to VINn to generate output voltage signals Y1to Yn. The channel amplifying circuit141amay include channel amplifiers OP_CH1—a, OP_CH2—aand OP_CH3—a.

The bias current control signal generating circuit150aofFIG. 10may adjust the bias current in response to bits D6and D7of the gray code, as well as the bias current control signal VCON_IB. Therefore, the slew rate may be more precisely compensated. The bits D6and D7of the gray code may be selected codes from the output signals D1to Dn of the data latch circuit120ofFIG. 1.

FIG. 11illustrates an embodiment of a channel amplifier in a channel amplifying circuit of the output buffer circuit ofFIG. 10. Referring toFIG. 11, the channel amplifier OP_CH1—amay include a differential input unit146, an upper bias unit142a, a lower bias unit144a, a load stage147, and an output stage148.

The differential input unit146may include a P-type differential input unit and an N-type differential input unit, and may receive an input voltage signal VIN and an output voltage signal VOUT in a differential mode. The P-type differential input unit may include PMOS transistors MP1and MP2, and the N-type differential input unit may include NMOS transistors MN1and MN2.

The upper bias unit142amay be electrically connected to the P-type differential input unit, connect the P-type differential input unit to a supply voltage VDD, and adjust a magnitude of a bias current supplied to the P-type differential input unit in response to the bias current control signal VCON_IB and bits D6and D7of a gray code.

The lower bias unit144amay be electrically connected to the N-type differential input unit, connect the N-type differential input unit to a ground voltage, and adjust a magnitude of a bias current supplied to the N-type differential input unit in response to the bias current control signal VCON_IB and the bits D6and D7of the gray code.

The load stage147may be electrically connected to the differential input unit146, and operate as a load of the differential input unit146. The output stage148may be electrically connected to the load stage147, and connect an output terminal of the load stage147to the supply voltage VDD or the ground.

The upper bias unit142amay include a first PMOS transistor MP3, a second PMOS transistor MP4, a third PMOS transistor MP5, a fourth PMOS transistor MP6, a first switch SW1, a second switch SW3, and a third switch SW5.

The first PMOS transistor MP3may have a source connected to the supply voltage VDD, a gate to which a first bias voltage VB1is applied, and a drain connected to the P-type differential input unit. The second PMOS transistor MP4may have a source connected to the supply voltage VDD, and a gate to which the first bias voltage VB1is applied. The third PMOS transistor MP5may have a source connected to the supply voltage VDD, and a gate to which the first bias voltage VB1is applied. The fourth PMOS transistor MP6may have a source connected to the supply voltage VDD, and a gate to which the first bias voltage VB1is applied.

The first switch may be coupled between a drain of the second PMOS transistor MP4and the P-type differential input unit, and turned on or off in response to the bias current control signal VCON_IB. The second switch may be coupled between a drain of the third PMOS transistor MP5and the P-type differential input unit, and turned on or off in response to a first bit D6of a gray code. The third switch SW5may be coupled between a drain of the fourth PMOS transistor MP6and the P-type differential input unit, and turned on or off in response to a second bit D7of the gray code.

The size of the second PMOS transistor MP4may be less than (e.g., a half of) that of the first PMOS transistor MP3, the size of the third PMOS transistor MP5may be less than (e.g., one fourth of) the first PMOS transistor MP3, and the size of the fourth PMOS transistor MP6may be less than (e.g., one eighth of) the first PMOS transistor MP3.

The lower bias unit144amay include a first NMOS transistor MN3, a second NMOS transistor MN4, a third NMOS transistor MN5, a fourth NMOS transistor MN6, a first switch SW2, a second switch SW4, and a third switch SW6.

The first NMOS transistor MN3may have a source connected to the ground voltage, a gate to which a second bias voltage VB2is applied, and a drain connected to the N-type differential input unit. The second NMOS transistor MN4may have a source connected to the ground voltage, and a gate to which the second bias voltage VB2is applied. The third NMOS transistor MN5may have a source connected to the ground voltage, and a gate to which the second bias voltage VB2is applied. The fourth NMOS transistor MN6may have a source connected to the ground voltage, and a gate to which the second bias voltage VB2is applied.

The first switch SW2may be coupled between a drain of the second NMOS transistor MN4and the N-type differential input unit, and turned on or off in response to the bias current control signal VCON_IB. The second switch SW4may be coupled between a drain of the third NMOS transistor MN5and the N-type differential input unit, and turned on or off in response to the first bit of a gray code D6. The third switch SW6may be coupled between a drain of the fourth NMOS transistor MN6and the N-type differential input unit, and turned on or off in response to the second bit D7of the gray code.

The size of the second NMOS transistor MN4may be less than (e.g., half of) the first NMOS transistor MN3, the size of the third NMOS transistor MN5may be less than (e.g., one fourth of) the first NMOS transistor MN3, and the size of the fourth NMOS transistor MN6may be less than (e.g., one eighth of) the first NMOS transistor MN3.

FIG. 12illustrates a diagram illustrating tail current with respect to bit values of a gray code, and a slew rate of an output voltage with respect to a magnitude of the tail currents in a channel amplifier ofFIG. 11.

Referring toFIG. 12, a magnitude of a tail current of the output signals may be configured to be adjusted according to a combination of bits of the gray code. For example, when D6=0 and D7=0, the additional current having the lowest level may be supplied to channel amplifiers. When D6=1 and D7=1, the additional current having the highest level may be supplied to channel amplifiers. As the magnitudes of the tail currents Itail1, Itail2and Itail3increase, a level transition of the output voltage of the channel amplifiers may be faster. That is, as the magnitudes of the tail currents Itail1, Itail2and Itail3increase, the slew rate may increase.

FIGS. 13 and 14illustrate embodiments of layouts of a source driving circuit. Referring toFIG. 13, the bias current control signal generating circuit230may be located between channel amplifying circuits210and220in the source driving circuit200. Referring toFIG. 14, the bias current control signal generating circuits330_1and330_2may be located an outer portion of channel amplifying circuits310and320in the source driving circuit300. That is, the bias current control signal generating circuits330_1and330_2may be located on both ends of the source driving circuit300.

FIG. 15illustrates an embodiment of liquid crystal display (LCD) device1000that may include any of the embodiments of the source driving circuit described herein. Referring toFIG. 13, the LCD device1000may include a controller1100, a gate driving circuit1200, a source driving circuit1300, a liquid crystal panel1400, and a gray voltage generator1500.

The liquid crystal panel1400may include TFTs (Thin Film Transistors) located at each intersection of the matrix. The TFT may have a source receiving a source signal (also called a “data signal”) and a gate receiving a gate signal (also called a “scan signal”). A storage capacitor CST and a liquid crystal capacitor CLC may be connected between a drain of the TFT and a common voltage VCOM. The liquid crystal panel1400may receive the gate signals through gate lines G1to Gn, and the source signals through source lines D1to Dm, respectively. The gate driving circuit1200may produce the gate signals by combining an on-voltage Von and an off-voltage Voff, and apply the gate signals to the gate lines G1to Gn.

The gray voltage generator1500may generate positive and negative gray scale voltages GMA associated with the brightness of the LCD device1000.

The source driving circuit1300may perform a digital-to-analog (D/A) conversion on data DATA received from the controller1100by using the gray scale voltages GMA output from the gray voltage generator1500, and apply the converted data to the source lines D1to Dm.

The controller1100may receive RGB video signals R, G and B and control signals. The control signals may include, for example, a vertical sync signal Vsync, a horizontal sync signal Hsync, a main clock signal MCLK, a data enable signal DE, and so on. The controller1100may generate source control signals CONT1and gate control signals CONT2based on the control signals. The controller1100may also properly process the RGB video signals R, G and B, so as to meet operation conditions of the liquid crystal panel1400. Then, the controller1100may transmit the gate control signals CONT2to the gate driving circuit1200, and transmit the source control signals CONT1and the video signals DATA (R, G, B) to the source driving circuit1300.

The gate driving circuit1200and the source driving circuit1300may include a plurality of gate drive integrated circuits (IC) and a plurality of source drive ICs, respectively. The data DATA may determine a gray level with respect to each pixel. The source driving circuit1300may apply the source signals to the source lines arranged on the liquid crystal panel1400, and the gate driving circuit1200may apply the gate signals to the gate lines arranged on the liquid crystal panel1400.

The source driving circuit1300included in the LCD device1000ofFIG. 15may have the same structure of a source driving circuit100ofFIG. 1. Therefore, the LCD device1000may include the output buffer circuit according to any of the embodiments described herein.

The output buffer circuit included in the LCD device1000may include a bias current control signal generating circuit and a channel amplifying circuit. The bias current control signal generating circuit may include a reference operational amplifier, and perform an exclusive OR operation on an input signal and an output signal of the reference operational amplifier to generate a bias current control signal. The channel amplifying circuit may compensate for a slew rate in response to the bias current control signal, and perform buffering on a plurality of input voltage signals to generate a plurality of output voltage signals.

The output buffer circuit may further compensate for the slew rate in response to a gray code of a source driving circuit of a display device. A magnitude of a tail current of the plurality of output signals may be adjusted according to a combination of bits of the gray code. The slew rate may increase according to an increase of the tail current. That is, as the magnitude of the tail current of an output voltage signal increases, a transition time of the output voltage signal may become shorter.

FIG. 16illustrates an embodiment of a method of operating a source driving circuit of a display device. Referring toFIG. 16, the method of operating a source driving circuit of a display device may include the following operations:

(1) generating a pulse signal based on a clock signal and a input/output control signal using a shift register (S1);

(2) latching data according to a shift sequence of the shift register and outputting the data as digital input signals in response to a load signal (S2);

(3) generating input voltage signals corresponding to the digital input signals using a gray voltage (S3);

(4) performing an exclusive OR operation on an input signal and an output signal of a reference operational amplifier to generate a bias current control signal (S4).

(5) compensating for a slew rate in response to the bias current control signal (S5).

(6) performing buffering on the input voltage signals to generate source signals (S6).

FIG. 17illustrates another embodiment of a method of operating a source driving circuit of a display device. Referring toFIG. 17, the method of operating a source driving circuit of a display device may include the following operations:

(1) generating a pulse signal based on a clock signal and a input/output control signal using a shift register (S1);

(2) latching data according to a shift sequence of the shift register and outputting the data as digital input signals in response to a load signal (S2);

(3) generating input voltage signals corresponding to the digital input signals using a gray voltage (S3);

(4) performing an exclusive OR operation on an input signal and an output signal of a reference operational amplifier to generate a bias current control signal (S4).

(5) compensating for a slew rate in response to the bias current control signal (S5).

(6) compensating for the slew rate in response to a gray code (S7).

(7) performing buffering on the input voltage signals to generate source signals (S6).

In the above, an output buffer circuit, a source driving circuit including the output buffer circuit, and an LCD device having the source driving circuit were described. In other embodiments, the output buffer circuit and source driving circuit including the output buffer may be implemented in other types of display devices, including but not limited to a plasma display panel (PDP) and an organic light emitting diode (OLED).

By way of summation and review, one or more embodiments is directed to providing a source driving circuit to change a slew rate of the output signal, such that the output buffer circuit may be used for a high resolution and large scale panel, and have low power consumption.