Abstract: A system and method are disclosed for performing on die jitter tolerance testing. A set of clocks are generated based on an input signal. The set of clocks include in an in-phase signal based on the data switching edge of the input signal. Additionally, the set of clocks include an inverted clock phase shifted by 180 degrees, and a pair of clocks phase shifted positively and negatively by a certain number of degrees, ?. Data input is sampled based on the inverted clock and the two phase shifted clocks. The eye opening of the input signal can be determined based on whether each of the inverted clock and the two phase shifted clocks sample the correct data from the input signal at various ? values.

Abstract: A system and method are disclosed to control the power consumption of column drivers in a display system. A video input signal is received which has an active video period and a vertical blanking period between frames. A timing controller transmits a first video frame to a column driver. The timing controller transmits a column driver disable command during a vertical blanking period. Prior to the subsequent active video period, the timing controller transmits a column driver enable command. The timing controller proceeds to transmit a second video frame to the column driver. In one embodiment, the timing controller determines whether to disable and enable the column driver based on a refresh rate, the refresh rate calculated by the timing controller from the video input signal.

Abstract: A system and method are disclosed for performing on die jitter tolerance testing. A set of clocks are generated based on an input signal. The set of clocks include in an in-phase signal based on the data switching edge of the input signal. Additionally, the set of clocks include an inverted clock phase shifted by 180 degrees, and a pair of clocks phase shifted positively and negatively by a certain number of degrees, ?. Data input is sampled based on the inverted clock and the two phase shifted clocks. The eye opening of the input signal can be determined based on whether each of the inverted clock and the two phase shifted clocks sample the correct data from the input signal at various ? values.

Abstract: A system and method are disclosed for generating a high accuracy and low power on die reference clock. An LC clock is generated on die and a frequency divider lowers the LC clock frequency to a target reference frequency. An RCO clock is generated on die with an unknown initial frequency. The RCO clock and target reference clock are compared to determine in which direction the frequency of the RCO clock should be adjusted to move closer to the target reference frequency. A signal is sent causing a current source or capacitor in the RCO circuit to be modified. Therefore, the RCO clock frequency is adjusted. The RCO circuit is repeatedly adjusted until the RCO clock frequency is sufficiently accurate. The LC clock is disabled to conserve the power that would have been consumed in generating the LC clock.

Abstract: A system and method are disclosed for generating a high accuracy and low power on die reference clock. An LC clock is generated on die and a frequency divider lowers the LC clock frequency to a target reference frequency. An RCO clock is generated on die with an unknown initial frequency. The RCO clock and target reference clock are compared to determine in which direction the frequency of the RCO clock should be adjusted to move closer to the target reference frequency. A signal is sent causing a current source or capacitor in the RCO circuit to be modified. Therefore, the RCO clock frequency is adjusted. The RCO circuit is repeatedly adjusted until the RCO clock frequency is sufficiently accurate. The LC clock is disabled to conserve the power that would have been consumed in generating the LC clock.

Abstract: A system and method are disclosed for embedding a timing controller on column drivers which, among other advantages, reduces power consumption and size constraints. A standalone timing controller is eliminated by splitting a video input signal and delivering the signal to each of the column drivers. Timing controller functionality is embedded in each of the column drivers to allow the column drivers to process the received video signal. An auxiliary input used for communication between column drivers and an external system is received by a master column driver. The master column driver communicates with slave column drivers to enable point to point communication between each column driver and the external system.

Abstract: A system and a method are disclosed for a hybrid mode re-driver which, among other advantages, reduces power consumption while maintaining signal integrity. Equalization is performed on a signal to remove distortions such as inter-symbol interference. The signal is then analyzed and the quality of the signal is assessed. In some cases, retiming is then performed on the signal to remove additional signal distortions. In other cases, retiming is not performed and is transmitted to a driver while bypassing retiming components. When retiming components are bypassed, the retiming components are placed in a state of reduced power consumption to reduce system power consumption.

Abstract: A system and a method are disclosed for an intra-panel communication interface which, among other advantages, enhances system reliability and reduces bus width. A timing controller initializes communication with a plurality of source drivers by transmitting link data through a plurality of data channels and monitors source driver status through an auxiliary status channel. The plurality of source drivers share the auxiliary status channel to indicate their status. The timing controller transmits display data to a source driver through a data channel. The display data includes a request for status data from the source driver. The source driver transmits the requested status data to the timing controller via the auxiliary status channel.

Abstract: A system and a method for exchanging communication data between devices using a bi-directional communication channel are disclosed. A combiner is coupled to a source device via first bi-directional configuration channel and to a sink device via a second bi-directional configuration channel. Upon receiving data from the first bi-directional configuration channel and not receiving data from the second bi-directional configuration channel, the combiner transmits the received data to the sink device using the second bi-directional configuration channel and prevents data transmission from the sink device to the source device using the second bi-directional configuration channel.

Abstract: A system and a method for exchanging communication data between devices using a bi-directional communication channel are disclosed. A combiner is coupled to a source device via first bi-directional configuration channel and to a sink device via a second bi-directional configuration channel. Upon receiving data from the first bi-directional configuration channel and not receiving data from the second bi-directional configuration channel, the combiner transmits the received data to the sink device using the second bi-directional configuration channel and prevents data transmission from the sink device to the source device using the second bi-directional configuration channel.

Abstract: A system and a method for communicating configuration data between a source device and a sink are described. An active buffer receives data from an auxiliary communication channel which communicates data between the source device and the sink device. The active buffer modifies data received from the auxiliary communication channel. For example, the active buffer amplifies the received data or electrically reshapes the received data. The modified data is then transmitted from the active buffer to a destination device. In one embodiment, the auxiliary communication channel is bi-directional and upon receiving data from a first device, the active buffer is modified to permit uni-directional transmission of data from the first device to a second device.

Abstract: Systems and methods provide synchronization techniques across a number of communication channels. For example, in accordance with an embodiment of the present invention, a synchronization scheme is disclosed for synchronizing across multiple data transmission channels, with each transmission channel multiplexing parallel data into serial data.

Abstract: A circuit includes a configurable receiver circuit, a multiplexer or demultiplexer coupled to the configurable receiver circuit, and a configurable driver circuit coupled to the multiplexer or demultiplexer. The configurable receiver circuit generates an internal format signal which is received by the multiplexer or demultiplexer. The configurable driver circuit receives the internal format signal from the multiplexer or demultiplexer.

Abstract: A circuit for calibrating a resistance value on an integrated circuit includes a resistor network, a reference voltage generator, a comparator, a servo loop, and a shift register. The resistor network includes a plurality of resistor and switch pairs in parallel. The resistor network further includes a servo resistor in series with a servo resistor switch such that the servo resistor and servo resistor switch are in parallel with the plurality of resistor and switch pairs. The servo loop generates a shift register gating signal and includes a current sample register for storing a current comparator output data value and a previous sample register for storing a previous comparator output data value. The shift register, upon receipt of a shift register gating signal at a first state, inputs the current comparator output data value to shift data bits through the shift register.

Abstract: A circuit includes a configurable receiver circuit, a multiplexer or demultiplexer coupled to the configurable receiver circuit, and a configurable driver circuit coupled to the multiplexer or demultiplexer. The configurable receiver circuit generates an internal format signal which is received by the multiplexer or demultiplexer. The configurable driver circuit receives the internal format signal from the multiplexer or demultiplexer.

Abstract: A current mode logic circuit includes a current mode logic driver circuit and a transistor biasing improvement circuit. The transistor biasing improvement circuit includes a first current source coupled to a first output node of the current mode logic driver circuit and a second current source coupled to a second output node of the current mode logic driver circuit. The first current source and the second current source raise a common mode voltage at the first output node and the second output node.

Abstract: Systems and methods for on-chip resistor calibration are disclosed. A circuit for calibrating a resistance value on an integrated circuit includes a resistor network, a reference voltage generator, a comparator, a servo loop, and a shift register. The resistor network includes a plurality of resistor and switch pairs in parallel. The resistor network further includes a servo resistor in series with a servo resistor switch such that the servo resistor and servo resistor switch are in parallel with the plurality of resistor and switch pairs. The servo loop generates a shift register gating signal and includes a current sample register for storing a current comparator output data value and a previous sample register for storing a previous comparator output data value. The shift register, upon receipt of a shift register gating signal at a first state, inputs the current comparator output data value to shift data bits through the shift register.

Abstract: An actively compensated CML circuit includes a CML buffer circuit and a bandwidth expansion circuit. The CML buffer circuit includes a first MOS transistor and a second MOS transistor in a differential pair configuration. A first load resistor is coupled to a first MOS transistor drain at a first output terminal and a second load resistor is coupled to a second MOS transistor drain at a second output terminal. The bandwidth expansion circuit is coupled to the CML buffer circuit in a source follower configuration. The bandwidth expansion circuit includes a third MOS transistor and a fourth MOS transistor. A capacitor is coupled across a third MOS transistor source and a fourth MOS transistor source. The fourth MOS transistor and the third MOS transistor generate a high pass function at the first output terminal and the second output terminal.

Abstract: A switched-capacitor ripple-smoothing filter includes a first pair of capacitors. The filter is configured such that either capacitor in the first pair may be reset and have a terminal coupled to a first input port and such that the remaining capacitor in the first pair is isolated from the first input port and has the terminal coupled to a first output port while the other capacitor is being charged. The filter further includes a second pair of capacitors, the filter being configured such that either capacitor in the second pair may be reset and have a terminal coupled to a second input port and such that the remaining capacitor in the second pair is isolated from the second input port and has the terminal coupled to a second output port while the other capacitor in the second pair is being charged. Advantageously, the filter is configured such that the capacitors in the first and second pair are reset responsive to the assertion of a single reset signal.

Abstract: A phase detector and control signal generator responds to a reference signal and a feedback signal to produce a non-delayed up and down signal. A programmable delay unit delays the non-delayed up and down signal to provide up and down signals for a charge pump. A divider configured to respond to the up and down signals provides a divided clock signal. A non-overlapped clock generator configured to respond to the divided clock signal to provide non-overlapped hold even and hold odd signals for the switched-capacitor ripple-smoothing filter.