Abstract: A method for displaying error rates of data channels of a display is provided. A timing controller of the display repeatedly transmits a test signal with a specific format to a first and a second source drivers of the display via a first and a second data channels of the display. During testing, a first number and a second number of times of the first source driver and the second source driver determining that the received test signal does not have the specific format are counted respectively. The first and the second source drivers control displaying of a first area and a second area of a panel of the display respectively according to the counted first and second numbers of times. Accordingly, the error rates of the data channels are presented on the panel of the display in a way that the error rates could be recognized more easily.

Abstract: A source driver includes a first drive channel circuit, a voltage controller and a first programmable voltage buffer unit. The first drive channel circuit receives a first pixel data and a first reference voltage group, for driving the display device. The voltage controller receives a voltage command during a line data transmitting period, a horizontal blanking period or a vertical blanking period for generating a first reference voltage configuration data. The first programmable voltage buffer unit is coupled to the voltage controller and the first drive channel circuit, and receives the first reference voltage configuration data for applying the first reference voltage group to the first drive channel circuit. Furthermore, a method for driving a display device is also provided.

Abstract: A source driver includes a first drive channel circuit, a voltage controller and a first programmable voltage buffer unit. The first drive channel circuit receives a first pixel data from the timing controller via a data bus, converts the first pixel data to a first drive voltage according to a first reference voltage group, and drives a display panel by the first drive voltage. The voltage controller receives a voltage command from the timing controller, generates and changes a first reference voltage configuration data according to the voltage command. The first programmable voltage buffer unit is coupled to the voltage controller and the first drive channel circuit, and receives the first reference voltage configuration data to generate and adjust the first reference voltage group for applying to the first drive channel circuit. Furthermore, a method for updating a new gamma curve by the source driver is also provided.

Abstract: The present invention discloses an integrated source driver for a liquid crystal display device. The integrated source driver includes a reference voltage generating circuit, for providing a plurality of adjustable voltage ranges within a supply voltage and a ground level, and a reference voltage selecting circuit, including a plurality of digital to analog converters, for selecting and generating a plurality of internal reference voltages from the plurality of adjustable voltage ranges, respectively. The plurality of adjustable voltage ranges decrease progressively.

Abstract: A self-detection charge sharing module for a liquid crystal display device is disclosed. The self-detection charge sharing module includes at least one detecting unit, for detecting a plurality of input voltages of a plurality of operational amplifiers driving a plurality of data line sand a plurality of output voltage of the plurality of data line, to generate at least one detecting result, and at least one charge sharing unit, for conducting connection between at least one first data line and at least one second data line among the plurality of data line when the at least one detecting result indicates at least one corresponding first input voltage and at least one corresponding second input voltage among the plurality of input voltage have opposite voltage variation direction and vary toward each other. The at least one first input voltage and the at least one second input voltage maintain respective polarities.

Abstract: A panel display apparatus is provided which includes a timing controller, a plurality of source drivers, a first data path, and a second data path. The first data path and the second data path are both coupled between the timing controller and the source drivers. The timing controller transmits multiple display data to the source drivers via the first data path. When the source drivers detect an event (e.g. error event), the source drivers transmit at least one event data (e.g. notification data) to the timing controller via the second data path to notify the timing controller that event correction (e.g. error correction) is needed.

Abstract: A source driver includes a first drive channel circuit, a voltage controller and a first programmable voltage buffer unit. The first drive channel circuit receives a first pixel data from the timing controller via a data bus, converts the first pixel data to a first drive voltage according to a first reference voltage group, and drives a display panel by the first drive voltage. The voltage controller receives a voltage command from the timing controller, generates and changes a first reference voltage configuration data according to the voltage command. The first programmable voltage buffer unit is coupled to the voltage controller and the first drive channel circuit, and receives the first reference voltage configuration data to generate and adjust the first reference voltage group for applying to the first drive channel circuit. Furthermore, a method for updating a new gamma curve by the source driver is also provided.

Abstract: A method for displaying error rates of data channels of a display is provided. A timing controller of the display repeatedly transmits a test signal with a specific format to a first and a second source drivers of the display via a first and a second data channels of the display. During testing, a first number and a second number of times of the first source driver and the second source driver determining that the received test signal does not have the specific format are counted respectively. The first and the second source drivers control displaying of a first area and a second area of a panel of the display respectively according to the counted first and second numbers of times. Accordingly, the error rates of the data channels are presented on the panel of the display in a way that the error rates could be recognized more easily.

Abstract: A flat panel display with multi-drop interfaces is disclosed. The flat panel display with multi-drop interfaces includes a plurality of driver chips having a plurality of respective hardware setting values via a hardware setting, and a timing controller for transmitting at least one signal to the plurality of driver chips via at least one multi-drop interface, wherein the timing controller and a specific driver chip among the plurality of driver chips negotiate with each other according to a corresponding specific respective hardware setting value among the plurality of respective hardware setting values.

Abstract: An amplifier includes an output stage circuit, a current source, a PMOS input pair, an NMOS input pair and a current transferring circuit. The output stage circuit is electrically coupled to a supply voltage and a ground voltage. The current source has a node to provide a current. The PMOS input pair is coupled to the node and the ground voltage and controlled by an input voltage. The NMOS input pair coupled to the supply voltage is controlled by the input voltage. The current transferring circuit is coupled to the node and the NMOS input pair. When the input voltage is less than a specific value, the current flows into the PMOS input pair through the node. When the input voltage is larger than or equal to the specific value, the current flows into the NMOS input pair through the node and the current transferring circuit.

Abstract: A data transmission device includes a data division unit for receiving an original transmission data and dividing the original transmission data into a plurality of division data; a data generation unit for generating a plurality of packet data according to the plurality of division data and a plurality of clock data, wherein each of the clock data is a multi-bit data; and a data output unit for outputting the plurality of packet data to a data reception device; where each of the packet data includes a division data and a clock data, each of the packet data corresponds to a packet data period, and the division data corresponds to a division data period of the packet data period and the clock data corresponds to a clock period of the packet data period.

Abstract: An operational amplifier including a primary differential input pair, a primary tail current source module, N auxiliary differential input pairs, and N auxiliary tail current source modules is disclosed. A first and a second input terminal of the primary differential input pair respectively receive a first and a second input signal, wherein first input signal and the second input signal are differential to each other. The primary tail current source module supplies a tail current to the primary differential input pair during a first time interval. A first and a second input terminal of each of the auxiliary differential input pairs respectively receive the first and the second input signal. Each of the auxiliary tail current source modules supplies an auxiliary tail current to the corresponding auxiliary differential input pair during a second time interval. The first time interval and the second time interval partially overlap each other.

Abstract: An operational amplifier providing an output voltage signal to drive a load in response to an input voltage signal is provided. The operational amplifier includes a first input stage and a second input stage, a second stage and an output enable switch. The first input stage provides a first intermediate signal according to the voltages of an input and an output voltage signals in a transitional state. The second input stage provides a second intermediate signal according to the input and the output voltage signals in a steady state. The second stage provides the output voltage signal to an output node according to the first and the second intermediate signals in the transitional and the steady states respectively. The output enable switch is enabled in an output enable period to drive the load with the output voltage signal.

Abstract: A spread-spectrum circuit including an inverter, a current source, a control unit and a shaping circuit is provided. An input terminal of the inverter receives an original clock signal. The current source is coupled to a current transmission terminal of the inverter. The control unit includes a control circuit, and changes the current magnitude of the current source according to the original clock signal to control the charging/discharging speed of an output terminal of the inverter, so that the output terminal outputs a voltage signal. The shaping circuit shapes the voltage signal into a spread-spectrum clock signal.

Abstract: An amplifier includes an output stage circuit, a current source, a PMOS input pair, an NMOS input pair and a current transferring circuit. The output stage circuit is electrically coupled to a supply voltage and a ground voltage. The current source has a node to provide a current. The PMOS input pair is coupled to the node and the ground voltage and controlled by an input voltage. The NMOS input pair coupled to the supply voltage is controlled by the input voltage. The current transferring circuit is coupled to the node and the NMOS input pair. When the input voltage is less than a specific value, the current flows into the PMOS input pair through the node. When the input voltage is larger than or equal to the specific value, the current flows into the NMOS input pair through the node and the current transferring circuit.

Abstract: A coupling isolation method for preventing a load signal from coupling into an operational amplifier is disclosed. The coupling isolation method includes generating a system signal before the operational amplifier outputs a computation result, switching off a Miller compensation signal path of the operational amplifier at a first time point according to the system signal, and electrically connecting an output end of the operational amplifier and a load at a second time point according to the system signal to output the computation result.

Abstract: A spread-spectrum circuit including an inverter, a current source, a control unit and a shaping circuit is provided. An input terminal of the inverter receives an original clock signal. The current source is coupled to a current transmission terminal of the inverter. The control unit includes a control circuit, and changes the current magnitude of the current source according to the original clock signal to control the charging/discharging speed of an output terminal of the inverter, so that the output terminal outputs a voltage signal. The shaping circuit shapes the voltage signal into a spread-spectrum clock signal.

Abstract: A coupling isolation method for preventing a load signal from coupling into an operational amplifier is disclosed. The coupling isolation method includes generating a system signal before the operational amplifier outputs a computation result, switching off a Miller compensation signal path of the operational amplifier at a first time point according to the system signal, and electrically connecting an output end of the operational amplifier and a load at a second time point according to the system signal to output the computation result.

Abstract: A two-channel operational amplifier circuit includes a first operational amplifier and a second operational amplifier. In a first frame period, the two-channel operational amplifier circuit switches a first input stage, a first gain stage and a first output stage to work between a working voltage and a half working voltage, and switches a second input stage, a second gain stage and a second output stage to work between the half working voltage and a ground voltage. In a second frame period, the two-channel operational amplifier circuit switches the second input stage and the second gain stage to work between the working voltage and the half working voltage, and switches the first input stage and the first gain stage to work between the half working voltage and the ground voltage.

Abstract: A low pass filter de-glitch circuit is disclosed herein, it includes a first short pulse resetting circuit, a second short pulse resetting circuit having MOS transistors and a low pass filtering circuit having a capacitor coupled with an inverter. Forgoing circuits are cascode together and then connected to a buffer. The buffer provides two complementary signals which are served as control signals feedbacked to the first short pulse resetting circuit and the second short pulse resetting circuit. Utilizing the driving large current capability the MOS transistors have, the low pass filter de-glitch circuit can reset the capacitor rapidly. Therefore the circuit can filter those glitch signals.