Abstract: A phase lock loop frequency synthesizer includes a phase rotator in the feedback path of the PLL. The PLL includes a phase detector, a low passn filter, a charge pump, a voltage controlled oscillator (“VCO”), and a feed back path connecting output of the VCO to the phase detector. The feedback path includes a phase rotator connected to the output of the VCO and to an input of a frequency divider. Coarse frequency control is implemented by adjusting the input reference frequency to the phase detector or by adjusting the divider ratio of the frequency divider. Fine frequency control is achieved by increasing or decreasing the rotation speed of the phase rotator. The phase rotator constantly rotates phase of the VCO output, thereby causing a frequency shift at the output of the phase rotator. The rotation speed of the phase rotator is controlled by an accumulator and a digital frequency control word.

Abstract: Systems and methods for pulse stretching architectures for phase alignment of multi-frequency clocks for high speed data acquisitions are disclosed. A high speed data acquisition system includes a transmitter and a receiver. The receiver includes a multi-frequency clock generator that generates a plurality of clock signals, a pattern check module that detects a test pattern received from the transmitter and outputs a stretch command signal, and a stretch pulse generator that receives the stretch command signal and provides a stretch pulse signal that aligns the phases of the plurality of clock signals generated by the multi-frequency clock generator. Methods for initializing and shifting multi-phase clock signals to optimize error performance of a high speed data acquisition system are also provided.

Abstract: A voltage regulator circuit includes a single high voltage regulator, and a plurality of parallel low voltage regulators capable of receiving an intermediate voltage from the high-voltage regulator, and capable of outputting a regulated output voltage. The intermediate voltage is no higher than a breakdown voltage of the low voltage regulators.

Abstract: A phase lock loop frequency synthesizer includes a phase rotator in the feedback path of the PLL. The PLL includes a phase detector, a low pass filter, a charge pump, a voltage controlled oscillator (“VCO”), and a feed back path connecting output of the VCO to the phase detector. The feedback path includes a phase rotator connected to the output of the VCO and to an input of a frequency divider. Coarse frequency control is implemented by adjusting the input reference frequency to the phase detector or by adjusting the divider ratio of the frequency divider. Fine frequency control is achieved by increasing or decreasing the rotation speed of the phase rotator. The phase rotator constantly rotates phase of the VCO output, thereby causing a frequency shift at the output of the phase rotator. The rotation speed of the phase rotator is controlled by an accumulator and a digital frequency control word.

Abstract: An environmental-compensated oscillator includes a reference clock waveform generator; a phase locked loop receiving the reference clock waveform and outputting a phase locked clock waveform; and a sensor outputting a voltage corresponding to an environmental parameter of the generator. The voltage is used by the PLL to compensate the phase locked clock waveform. The PLL includes a phase detector, a charge pump coupled to an output of the phase detector, a low pass filter coupled to an output of the charge pump, a voltage controlled oscillator (“VCO”) coupled to an output of the low pass filter, and a feedback path coupled between an output of the VCO and the phase detector, wherein the feedback path includes a phase rotator capable of fine tuning an output frequency of the VCO responsive to a frequency of an input clock. An accumulator is coupled to the phase rotator and supplies the input clock to the phase rotator. The phase rotator finely tunes the VCO output frequency.

Abstract: A charge pump includes a resistor divider connected between an output voltage node and ground and a comparator inputting a reference voltage at one input, and a divided voltage from the resistor divider at another input. A digital control circuit is enabled by the comparator. A first transistor and a second transistor are in series between an input voltage node and the ground, both transistors controlled by the digital control circuit. A pump capacitor is connected between to the output voltage node and between the first and second transistor, and being charged by turning the first and second transistors on and off. A first diode is between the pump capacitor and the input voltage node. A second diode between the pump capacitor and the output voltage node. A reservoir capacitor between the output voltage node and ground. The digital control circuit comprises a first shift register.

Abstract: A direct conversion satellite tuner is fully integrated on a common substrate. The integrated tuner receives an RF signal having a plurality of channels and down-converts a selected channel directly to baseband for further processing. The integrated tuner includes on-chip local oscillator generation, tunable baseband filters, and DC Offset cancellation. The integrated tuner can be implemented in a completely differential I/Q configuration for improved electrical performance. The entire direct conversion satellite tuner can be fabricated on a single semiconductor substrate using standard CMOS processing, with minimal off-chip components. The tuner configuration described herein is not limited to processing TV signals, and can be utilized to down-convert other RF signals to an IF frequency or baseband.

Abstract: A first MOS-on-NWELL device is formed on a substrate and has its pickup terminals optionally connected together. A second MOS-on-NWELL device is formed on the substrate and has its pickup terminals optionally connected together. A gate of the first MOS-on-NWELL device is connected to the pickup terminals of the second MOS-on-NWELL device. A gate of the second MOS-on-NWELL device is connected to the pickup terminals of the first MOS-on-NWELL device. A first PMOS transistor is formed on a substrate and has its source and drain terminals connected together. A second PMOS transistor is formed on a substrate and has its source and drain terminals connected together. A gate of the first PMOS transistor is connected to the source and drain terminals of the second PMOS transistor. A gate of the second PMOS transistor is connected to the source and drain terminals of the first PMOS transistor.

Abstract: The present invention is directed to an apparatus and method for reducing a parasitic capacitance in an integrated circuit. The apparatus includes a substrate and a biasing device. The substrate has a circuit disposed thereon, wherein a first capacitance exists between the substrate and an element of the circuit. The biasing device DC biases a first portion of the substrate to a voltage different than a voltage of a second portion of the substrate, thereby inducing a second capacitance between the first portion of the substrate and the second portion of the substrate. The second capacitance is in series with the first capacitance.

Abstract: A power supply multiplexing circuit including a first supply voltage input. A first pair of cascoded PMOS transistors are in series with the first supply voltage input. A first native NMOS transistor is in series with the first pair of cascoded PMOS transistors. Also, a second supply voltage input and a second pair of cascoded PMOS transistors are in series with the second supply voltage input; and a second native NMOS transistor in series with the second pair of cascoded PMOS transistors. The gates of the first and second native NMOS transistors are driven by two control signals out of phase with each other, and sources of the first and second native NMOS transistors are connected together to output an output voltage.

Abstract: A system for generating multiple synthesized clocks having an input terminal for receiving a reference signal, a phase locked loop circuit coupled to the input signal terminal, where the phase locked loop circuit is capable of generating a plurality of output signals that are frequency locked to the reference signal and having a plurality of different phases, a phase rotator coupled to the phase locked loop circuit, where the phase rotator generates an even greater plurality of phases.

Abstract: A semiconductor device that reduces the parasitic capacitance between a conductive trace and a substrate, and a method of fabricating the same. The semiconductor device includes a substrate, an insulator layer disposed upon the substrate, a conductive trace disposed upon the insulator layer, and an element disposed between the substrate and the conductive trace. A first capacitance exists between the conductive trace and the substrate and a second capacitance results between the conductive trace and the substrate due to the presence of the element. The second capacitance is in series with the first capacitance, thereby reducing an effective capacitance between the conductive trace and the substrate.

Abstract: Systems and methods for pulse stretching architectures for phase alignment of multi-frequency clocks for high speed data acquisitions are disclosed. A high speed data acquisition system includes a transmitter and a receiver. The receiver includes a multi-frequency clock generator that generates a plurality of clock signals, a pattern check module that detects a test pattern received from the transmitter and outputs a stretch command signal, and a stretch pulse generator that receives the stretch command signal and provides a stretch pulse signal that aligns the phases of the plurality of clock signals generated by the multi-frequency clock generator. Methods for initializing and shifting multi-phase clock signals to optimize error performance of a high speed data acquisition system are also provided.

Abstract: An I/O ESD protection configuration of an integrated circuit that includes an ESD protection circuit connected between an I/O pad and an internal circuit at a first node and to an inductor at a second node. The inductor is connected between the second node and an external power supply. The external power supply provides a high reverse bias voltage across a diode of the ESD protection circuit. An ESD clamp is connected between the second node and a ground. An ESD discharge current is shunted through the ESD protection circuit and through the ESD clamp during a positive I/O ESD event. The inductor can be chosen to tune out a parasitic capacitance of the ESD clamp. The inductor can also block high frequency signals between the I/O pad and the external power supply, thereby minimizing the parasitic capacitance of the diode of the ESD protection circuit at high frequency.

Abstract: A method and system, compatible with low-voltage CMOS technology, for controlling the charging of a battery. The method includes monitoring a battery voltage with respect to a threshold voltage. The method further includes coupling a charging control logic supply to ground, generating an active low first control signal, inverting the active low first control signal, and charging the battery at a first rate when the battery voltage is below the threshold voltage. The method further includes coupling the charging control logic supply to the battery voltage, generating an active high second control signal, and charging the battery at a second rate when the battery voltage exceeds the threshold voltage. The first charging rate is slower than the second charging rate. The method further includes supplying battery power to a charger line when the battery voltage exceeds the charger voltage, and suppressing a leakage current.

Abstract: Inter-device adaptable interfacing clock skewing. The invention is operable in either one of both of a transmit mode and a receive mode to perform skewing of a transmitted and/or a received signal. The operational parameters including frequency and phase may be determined during auto detect/auto negotiation, they may be programmed externally, or they may be user selected in various embodiments. A device may include a clock generator, one or more divider, and one or more delay cells internally to the device. If desired, a high frequency clock is generated within the device and then divided down to generate the appropriate clock signal that supports the communication and interaction between multiple devices. Registers and/or pins may be used to select the clock frequency and phase of output clock signals. The present invention supports multiple Ethernet protocols between multiple devices including 10BaseT, 100BaseT, and 1000BaseT.

Abstract: A system and method for implementing a common control bus in a multi-regulator power supply integrated circuit. The integrated circuit may, for example, comprise first and second power regulator modules that control at least one characteristic of respective power signals. The integrated circuit may also, for example, comprise a communication interface module that receives power control information related to operation of the first and second power regulator modules over a shared data bus. An exemplary method may, for example, comprise receiving power control information over a data bus. The method may also, for example, comprise determining which of a plurality of power regulators corresponds to the received power control information. The method may further, for example, comprise determining a regulator control signal, based at least in part on the received power control information, and provide the regulator control signal to the determined regulator(s) to control operation of the determined regulator(s).

Abstract: An integrated circuit formed on a semiconductor chip, comprising a low pass filter circuit having a first resistor of a first resistance value and a capacitor of a first capacitance value, wherein the first resistance value and the first capacitance value determine a corner frequency of the filter; and a tuning circuit having a second resistor of a second resistance value, a switched-capacitor of a third resistance value and a comparator that compares two voltage signals to produce a control signal, wherein the control signal adjusts the first and second resistance values as a function of the third resistance value. The corner frequency of the filter can be adjusted by varying one or more reference voltage signals. In combination, the corner frequency of the filter is adjusted by changing the frequency of a clock that controls the switched-capacitor to decrease the circuit sensitivity.

Abstract: A semiconductor device that reduces the parasitic capacitance between a conductive trace and a substrate, and a method of fabricating the same. The semiconductor device includes a substrate, an insulator layer disposed upon the substrate, a conductive trace disposed upon the insulator layer, and an element disposed between the substrate and the conductive trace. A first capacitance exists between the conductive trace and the substrate and a second capacitance results between the conductive trace and the substrate due to the presence of the element. The second capacitance is in series with the first capacitance, thereby reducing an effective capacitance between the conductive trace and the substrate.

Abstract: The accuracy of output power in a digital-to-analog converter (DAC) is critical in certain applications. When bi-CMOS technology is used to implement a DAC, a number of factors affect the gain accuracy of the DAC. The present invention provides a circuit architecture to reduce the variation in these factors to ensure the accuracy of the output power of a DAC. The architecture comprises a bandgap portion, replica circuit and a DAC. The bandgap portion of the architecture provides a constant voltage, while the replica circuit provide a correct current to drive the DAC.