Abstract: Power consumption of touch sensing operations for touch sensitive devices can be reduced by implementing one or more coarse scans to coarsely detect the presence or absence of an object touching or proximate to a touch sensor panel and dynamically adjusting the operation of the touch sensitive device to perform or not perform one or more steps of a fine scan based on the results of the one or more coarse scans. In some examples, the fine scan can be scheduled, and one or more steps of the fine scan can be aborted when no touch is detected at touch sensors scanned during the one or more steps. Sense channels unused due to the aborted fine scan steps can be powered down during aborted fine scan steps.

Abstract: A method and system to drive large off-chip loads, such as, for example, laser diodes, wherein the system includes an integrated circuit coupled to an external differential diode load. Alternatively, the external diode load may be driven single-ended. The integrated circuit includes a data buffer device and a clock buffer device. The integrated circuit also includes a multiplexer device coupled to the clock buffer device configured to multiplex a data input signal and a clock input signal received at respective inputs of the integrated circuit. If the external diode is single-ended, the data input signal is transmitted to the data buffer device, which is then used solely to drive the diode load. If the diode load is differential, the data buffer device receives the data input signal. At the same time, the multiplexer device receives both the data input signal and the clock input signal and selects the data signal to drive the clock buffer device.

Abstract: A method and system to drive large off-chip loads, such as, for example, laser diodes, wherein the system includes an integrated circuit coupled to an external differential diode load. Alternatively, the external diode load may be driven single-ended. The integrated circuit includes a data buffer device and a clock buffer device. The integrated circuit also includes a multiplexer device coupled to the clock buffer device configured to multiplex a data input signal and a clock input signal received at respective inputs of the integrated circuit. If the external diode is single-ended, the data input signal is transmitted to the data buffer device, which is then used solely to drive the diode load. If the diode load is differential, the data buffer device receives the data input signal. At the same time, the multiplexer device receives both the data input signal and the clock input signal and selects the data signal to drive the clock buffer device.

Abstract: A digital linear voltage regulator includes a comparator, a finite state machine, and a current digital-to-analog converter (DAC). The comparator is preferably coupled to receive a reference voltage and an operating voltage supplied to a dynamic load. The comparator generates, during a clock cycle, a binary output based on a comparison between reference and operating voltages. The finite state machine (FSM) is coupled to receive at least one control signal that indicates a target operating state for the digital linear voltage regulator. The FSM receives the binary output from the comparator and generates a digital word, during a clock cycle, based on the target operating state of the digital linear voltage regulator and on the binary output. The current DAC is coupled to the FSM, receives the digital word and delivers current at the desired voltage to the dynamic load.

Abstract: A method and system to drive large off-chip loads, such as, for example, laser diodes, wherein the system includes an integrated circuit coupled to an external differential diode load. Alternatively, the external diode load may be driven single-ended. The integrated circuit includes a data buffer device and a clock buffer device. The integrated circuit also includes a multiplexer device coupled to the clock buffer device configured to multiplex a data input signal and a clock input signal received at respective inputs of the integrated circuit. If the external diode is single-ended, the data input signal is transmitted to the data buffer device, which is then used solely to drive the diode load. If the diode load is differential, the data buffer device receives the data input signal. At the same time, the multiplexer device receives both the data input signal and the clock input signal and selects the data signal to drive the clock buffer device.

Abstract: A method and system for shaping an electronic pulse with a two-pulse response. An input node receives an initial electronic pulse and splits the electronic pulse into a first path and a second path. An output node combines together the first path and the second path into an output path, and transmits a shaped electronic pulse, matched to an output impedance. An Ethernet chip generates two pulses and transmits the pulses along a first path and a second path respectively. A power combiner/splitter combines together the pulses along the first path and the second path into an output path, and transmits a shaped electronic pulse, matched to an output impedance.

Abstract: A digital linear voltage regulator includes a comparator, a finite state machine, and a current digital-to-analog converter (DAC). The comparator is preferably coupled to receive a reference voltage and an operating voltage supplied to a dynamic load. The comparator generates, during a clock cycle, a binary output based on a comparison between reference and operating voltages. The finite state machine (FSM) is coupled to receive at least one control signal that indicates a target operating state for the digital linear voltage regulator. The FSM receives the binary output from the comparator and generates a digital word, during a clock cycle, based on the target operating state of the digital linear voltage regulator and on the binary output. The current DAC is coupled to the FSM, receives the digital word and delivers current at the desired voltage to the dynamic load.

Abstract: A digital linear voltage regulator includes a comparator, a finite state machine, and a current digital-to-analog converter (DAC). The comparator is preferably coupled to receive a reference voltage and an operating voltage supplied to a dynamic load. The comparator generates, during a clock cycle, a binary output based on a comparison between reference and operating voltages. The finite state machine (FSM) is coupled to receive at least one control signal that indicates a target operating state for the digital linear voltage regulator. The FSM receives the binary output from the comparator and generates a digital word, during a clock cycle, based on the target operating state of the digital linear voltage regulator and on the binary output. The current DAC is coupled to the FSM, receives the digital word and delivers current at the desired voltage to the dynamic load.

Abstract: A power converter within an integrated circuit (“IC”) for providing DC power to one or more function circuit, where the power converter has a transformer circuit for receiving an AC power signal and for supplying a transformed AC power signal. A converter circuit receives the transformed AC power signal and then converts the signal into a DC power signal supplied to one or more function circuit. The transformed AC power signal might either be stepped up or stepped down. The transformer circuit might comprise two coils, where a first coil is magnetically coupled to a second coil. The first coil is a first spiral and the second coil is a second spiral wherein an insulating material layer is disposed between the first spiral and the second spiral. The transformer circuit might include transformers connected in parallel or in series and may further be connected correspondingly to more than one converter circuit coupled in parallel.