A video display unit includes a display panel with gate drivers and source drivers. Each of the source drivers receives an encoded analog signal representing a video stream over a transmission medium and decodes the signal to produce samples for output to the display. Gate driver control signals synchronize the gate drivers with the source drivers. The source drivers are integrated with the display panel glass in part or in whole. Amplifiers and level shifters of each source driver are implemented on the panel glass and the collector and decoder are not. Or, the amplifiers, shifters and collector are implemented on the panel glass and the decoder is not. Or, the amplifiers, shifters, collector and decoder of each source driver are implemented on the panel glass. The source drivers may drive a display of a mobile device. Thin-film transistors are used to implement the source drivers on glass.

A integrated circuit device includes digital-to-analog converter (DAC) circuitry including a resistor DAC that includes a resistor-two-resistor DAC configured to receive a first sub-word that includes a most significant bit (MSB) of a digital input signal and to output an analog output signal representative of the first sub-word, a resistor ladder configured to receive the analog output signal and a second sub-word that includes an intermediate significant bit (ISB) of the digital input signal and to generate an analog interpolated signal. The resistor ladder includes a plurality of resistor elements connected in series with one another to define a plurality of tap nodes, wherein a respective tap node is arranged between every two adjacent ones of the resistor elements, and a switching circuit having plurality of switches, wherein each switch is configured to selectively connect a respective one of the tap nodes to an output of the resistor ladder to generate the analog interpolated signal.

A bias circuit includes a digital-to-analog converter configured to receive a digital input and output an analog signal; an integrator coupled to a first node that is coupled to the digital-to-analog converter and an amplifier, and coupled to a second node that is coupled to a positive input port of a first comparator and a negative input port of a second comparator; the digital signal processor coupled to an output port of the first comparator and an output port of the second comparator, and coupled to an input port of the digital-to-analog converter.

A bias circuit includes a digital-to-analog converter configured to receive a digital input and output an analog signal; an integrator coupled to a first node that is coupled to the digital-to-analog converter and an amplifier, and coupled to a second node that is coupled to a positive input port of a first comparator and a negative input port of a second comparator; the digital signal processor coupled to an output port of the first comparator and an output port of the second comparator, and coupled to an input port of the digital-to-analog converter.

A number of unit cells of a digital-to-analog converter (DAC) may be simultaneously activated to generate an analog signal according to a decoded digital signal. Latches may be used at one or more levels of decoding and may be activated according to a clock signal to recapture the at least partially decoded data signals to maintain/improve the synchronicity of activation of the unit cells. However, the latches may consume additional power during operation. As such, clock tracking techniques such as static clock tracking, dynamic clock tracking, or differential clock tracking may be utilized to generate a clock path activation signal that gates the clock signal and determines which latches to ignore (e.g., leave inactive). In this manner, instead of activating each latch for every digital signal, clock tracking may be implemented to deactivate latches that do not provide useful updates to the decoded digital signal received at the unit cells.

Methods and apparatus for controlling a power supply voltage for a switch driver in a digital-to-analog converter (DAC). An example DAC generally includes a plurality of DAC cells, each DAC cell comprising a current source, a first switch coupled in series with the current source at a first node, and a switch driver having an output coupled to a control input of the first switch; and calibration circuitry having a first input coupled to a first DAC cell in the plurality of DAC cells and having an output coupled to at least one of the plurality of DAC cells, the calibration circuitry being configured to sense a voltage of the first node in the first DAC cell and to control the power supply voltage for the switch driver in the at least one of the plurality of DAC cells, based on the sensed voltage of the first node.

Methods and apparatus for controlling a power supply voltage for a switch driver in a digital-to-analog converter (DAC). An example DAC generally includes a plurality of DAC cells, each DAC cell comprising a current source, a first switch coupled in series with the current source at a first node, and a switch driver having an output coupled to a control input of the first switch; and calibration circuitry having a first input coupled to a first DAC cell in the plurality of DAC cells and having an output coupled to at least one of the plurality of DAC cells, the calibration circuitry being configured to sense a voltage of the first node in the first DAC cell and to control the power supply voltage for the switch driver in the at least one of the plurality of DAC cells, based on the sensed voltage of the first node.

A ultra-high speed DAC apparatus (e.g., with a full sampling frequency not less than 20 GHz) may include one or more digital pre-coders and DAC modules. Each DAC module may include multiple current-mode DAC systems and a first power combiner. The gate length of transistors within each DAC module may be between 6 and 40 nm. Each current-mode DAC system includes a transmission line (e.g., 40 to 80 microns long) coupled to multiple interleaving sub-DAC systems (within the current-mode DAC systems) and the first power combiner. The first power combiner combines, without interleaving, analog signals that have been interleaved within the current-mode DAC systems. The impedance of the first power combiner matches the impedance of each of the current-mode DAC systems and a load of the first power combiner. A second power combiner combines, without interleaving, analog signals from the DAC modules.

The invention relates to improved convolutions of digital signals. When a first digital signal is convoluted with a second digital signal to obtain an output digital signal, to be converted afterwards using a limited number of bits. In order to prevent a loss of information, and therefore a degradation of the output digital signal upon the future conversion, at least one of the first and the second digital signal is formed of suitable values that store the information from the first digital signal within the most significant bits of the output digital signal.

The present application discloses a data converter (112). The data converter includes an input terminus (98), a digital-to-analog (D/A) converter (116) and a mapping unit (114). The input terminus is configured to receive an input signal. The D/A converter includes a plurality of D/A converter units configured to generate an output signal. The mapping unit is coupled between the input terminus and the D/A converter and is configured to cause the plurality of D/A conversion units to be equivalently arranged in a relative order in which the plurality of D/A conversion units are gated according to specific electrical characteristics of the plurality of D/A conversion units for digital-to-analog conversion. The present application further provides an A/D converter, a D/A converter and a related chip.