Some embodiments include a system comprising: a first control logic configured to receive a first trigger and generate a second trigger in response to the first trigger the second trigger having a delay relative to the first trigger of a configurable number of cycles of a counter of the first control logic; a second control logic configured to receive the second trigger and generate a third trigger in response to the second trigger the third trigger having a delay relative to the second trigger of a configurable number of cycles of a counter of the second control logic; and a third control logic configured to receive the second trigger and generate a fourth trigger in response to the second trigger the fourth trigger having a delay relative to the second trigger of a configurable number of cycles of a counter of the third control logic. A particle beam may be accelerated in response to the triggers.

Some embodiments include a system comprising: a first control logic configured to receive a first trigger and generate a second trigger in response to the first trigger the second trigger having a delay relative to the first trigger of a configurable number of cycles of a counter of the first control logic; a second control logic configured to receive the second trigger and generate a third trigger in response to the second trigger the third trigger having a delay relative to the second trigger of a configurable number of cycles of a counter of the second control logic; and a third control logic configured to receive the second trigger and generate a fourth trigger in response to the second trigger the fourth trigger having a delay relative to the second trigger of a configurable number of cycles of a counter of the third control logic. A particle beam may be accelerated in response to the triggers.

A data latch circuit and a pulse signal generator thereof are provided. The pulse signal generator includes a first buffer, a second buffer, a pull-up switch and an output buffer. The first buffer generates a first buffering signal according to an input signal and a feedback signal. The second buffer generates a second buffering signal according to the input signal and the first buffering signal. The pull-up switch pulls up the second buffering signal according to the first buffering signal. The output buffer generates at least one output pulse signal according to the second buffering signal. The output buffer further outputs the at least one output pulse signal to the first buffer to be the feedback signal.

A data latch circuit and a pulse signal generator thereof are provided. The pulse signal generator includes a first buffer, a second buffer, a pull-up switch and an output buffer. The first buffer generates a first buffering signal according to an input signal and a feedback signal. The second buffer generates a second buffering signal according to the input signal and the first buffering signal. The pull-up switch pulls up the second buffering signal according to the first buffering signal. The output buffer generates at least one output pulse signal according to the second buffering signal. The output buffer further outputs the at least one output pulse signal to the first buffer to be the feedback signal.

A clock filter filtering a glitch of an input clock to generate an output clock is provided. A first delay circuit inverts the input clock to generate an inverted clock and delays the inverted clock to generate a first processing clock. A second delay circuit delays the input clock to generate a second processing clock. A first setting circuit generates a reset clock according to the inverted clock and the first processing clock. A second setting circuit generates a set clock according to the input clock and the second processing clock. When the set clock changes from a first level to a second level, a third setting circuit sets the output clock at the second level. When the reset clock changes from the first level to the second level, the third setting circuit sets the output clock to the first level.

A clock filter filtering a glitch of an input clock to generate an output clock is provided. A first delay circuit inverts the input clock to generate an inverted clock and delays the inverted clock to generate a first processing clock. A second delay circuit delays the input clock to generate a second processing clock. A first setting circuit generates a reset clock according to the inverted clock and the first processing clock. A second setting circuit generates a set clock according to the input clock and the second processing clock. When the set clock changes from a first level to a second level, a third setting circuit sets the output clock at the second level. When the reset clock changes from the first level to the second level, the third setting circuit sets the output clock to the first level.

The present disclosure relates to an OLED display panel for minimizing the size of a bezel and includes: an active area including data lines, scan lines intersecting the data lines, and sub-pixels arranged at each intersection; and a stage of a GIP driving circuit distributed and arranged in a plurality of unit pixel regions driven by m (m being a natural number) scan lines in the active area, to supply scan pulses to the corresponding scan lines, wherein the active area further includes m GIP internal connection lines parts respectively adjacent to the m scan lines, and a plurality of internal connection lines for connecting elements constituting each stage is distributed and arranged in the m GIP internal connection line parts.

The present disclosure relates to an OLED display panel for minimizing the size of a bezel and includes: an active area including data lines, scan lines intersecting the data lines, and sub-pixels arranged at each intersection; and a stage of a GIP driving circuit distributed and arranged in a plurality of unit pixel regions driven by m (m being a natural number) scan lines in the active area, to supply scan pulses to the corresponding scan lines, wherein the active area further includes m GIP internal connection lines parts respectively adjacent to the m scan lines, and a plurality of internal connection lines for connecting elements constituting each stage is distributed and arranged in the m GIP internal connection line parts.

A circuit has a first window comparator determining whether a signal at a first input has a voltage higher than a first threshold but lower than a second threshold, and a second window comparator determining whether a signal at a second input has a voltage higher than the first threshold but lower than the second threshold. A logic circuit generates pulses in response to either the first window comparator determining that the signal at the first differential input has a voltage higher than the first threshold but lower than the second threshold or the second window comparator determining that the signal at the second input has a voltage higher than the first threshold but lower than the second threshold. A filter circuit receives the pulses from the logic circuit and generates a flag indicating that the signal is invalid, based upon pulses received from the logic circuit.

A circuit has a first window comparator determining whether a signal at a first input has a voltage higher than a first threshold but lower than a second threshold, and a second window comparator determining whether a signal at a second input has a voltage higher than the first threshold but lower than the second threshold. A logic circuit generates pulses in response to either the first window comparator determining that the signal at the first differential input has a voltage higher than the first threshold but lower than the second threshold or the second window comparator determining that the signal at the second input has a voltage higher than the first threshold but lower than the second threshold. A filter circuit receives the pulses from the logic circuit and generates a flag indicating that the signal is invalid, based upon pulses received from the logic circuit.