Abstract: A two-stage power converter is disclosed in which a second stage may command a first stage to adjust an output voltage from the first stage to compensate for PVT variations in the second stage. Alternatively, the second stage may adjust a clocking frequency to compensate for the PVT variations.

Abstract: Driver circuits with S-shaped gate drive voltage curves for ramp-up and ramp-down of power field effect transistors are presented. In ramp-up, the S-shaped curve rapidly ramps the gate voltage of the power FET to its threshold. This ramp-up is self-terminating. The gate voltage of the power FET is slewed through saturation with a time constant. After a predetermined time, the gate of the power FET is driven to approach the supply voltage level. In ramp-down, the S-shaped curve rapidly ramps the gate voltage of the power FET down to its threshold voltage. This ramp-down is self-terminating. The gate voltage of the power FET is slewed through saturation. The gate-source voltage of the power FET is rapidly ramped down to zero. Such S-shaped curves for the gate drive signal allow the control of the transition times of the gate drive signal to acceptable levels of voltage/current spikes and electromagnetic interference.

Abstract: An integrated circuit includes a first portion of a stacked ring oscillator coupled between a first supply voltage node and a common node, wherein the first supply voltage node provides a local supply voltage for the first portion and the common node provides a local ground for the first portion. The integrated circuit includes a second portion of the stacked ring oscillator coupled between the common node and a second supply voltage node wherein the common node provides a local supply voltage for the second portion and the second supply voltage node provides a local ground for the second portion. The integrated circuit also includes a voltage divider having a first resistive element coupled between the first supply node and the common node and a second resistive element coupled between the common node and the second supply node.

Abstract: A multi-phase switching power converter includes a panic mode detector that triggers the activation of each phase in an open-loop mode of operation in which an open-loop duty cycle is used that is greater than a closed-loop duty cycle used during closed-loop operation for the active phases.

Abstract: A two-stage multi-phase switching power converter operates its first stage during nominal operation responsive to a nominal clocking frequency and operates its second stage during the nominal operation responsive to a second-stage clocking frequency that is greater than the nominal clocking frequency. In response to an application of a load, the first stage temporarily increases its clocking frequency from the nominal clocking frequency and implements a fixed duty cycle.

Abstract: In one or more embodiments, a method comprises comparing an output voltage for a multi-phase DC-DC switching power converter to a reference voltage to produce an error voltage. The method further comprises, for a first inductor, generating a first dual-ramp voltage signal having a first DC voltage level, and level-shifting the first dual-ramp voltage signal to form a second dual-ramp voltage signal having a second DC voltage level different from the first DC voltage level. Further, the method comprises switching on a first power switch coupled to the first inductor according to a duty cycle determined responsive to a comparison of the second dual-ramp voltage signal to the error voltage, where the level-shifting of the first dual-ramp voltage signal adjusts the duty cycle of the first power switch to balance a current in the first inductor with a current in a second inductor for the multi-phase DC-DC switching power converter.

Abstract: An integrated circuit has at least two power domains. A first power domain has circuitry coupled between a first power supply terminal and a second power supply terminal. A second power domain has circuitry coupled between a third power supply terminal and a fourth power supply terminal. A complementary voltage regulator includes N-type and P-type voltage regulators. The N-type voltage regulator is coupled between the first and third power supply terminals and controls a first voltage level at the second power supply terminal. The P-type voltage regulator is coupled between the third and fourth power supply terminals and controls a second voltage level at the third power supply terminal. The N-type voltage regulator produces a mid-level supply voltage to the P-type regulator and a “ground” for the circuits in the first power domain. The P-type regulator circuit produces a “ground” for the N-type regulator and a mid-level supply voltage for the circuits in the second power-domain.

Abstract: An integrated circuit has at least two power domains. A first power domain has circuitry coupled between a first power supply terminal and a second power supply terminal. A second power domain has circuitry coupled between a third power supply terminal and a fourth power supply terminal. A complementary voltage regulator includes N-type and P-type voltage regulators. The N-type voltage regulator is coupled between the first and third power supply terminals and controls a first voltage level at the second power supply terminal. The P-type voltage regulator is coupled between the third and fourth power supply terminals and controls a second voltage level at the third power supply terminal. The N-type voltage regulator produces a mid-level supply voltage to the P-type regulator and a “ground” for the circuits in the first power domain. The P-type regulator circuit produces a “ground” for the N-type regulator and a mid-level supply voltage for the circuits in the second power-domain.

Abstract: A passive equalizer is provided. The passive equalizer includes a first resistive element, a first inductive element, a second resistive element, and a first variable capacitor. The first resistive element is coupled between an input node and an output node. The first inductive element and the second resistive element are coupled in series between the output node and a first voltage supply node. The first variable capacitor is coupled between the input node and a first node located between the first inductive element and the second resistive element.

Abstract: An integrated circuit includes a first portion of a stacked ring oscillator coupled between a first supply voltage node and a common node, wherein the first supply voltage node provides a local supply voltage for the first portion and the common node provides a local ground for the first portion. The integrated circuit includes a second portion of the stacked ring oscillator coupled between the common node and a second supply voltage node wherein the common node provides a local supply voltage for the second portion and the second supply voltage node provides a local ground for the second portion. The integrated circuit also includes a voltage divider having a first resistive element coupled between the first supply node and the common node and a second resistive element coupled between the common node and the second supply node.

Abstract: A passive equalizer is provided. The passive equalizer includes a first resistive element, a first inductive element, a second resistive element, and a first variable capacitor. The first resistive element is coupled between an input node and an output node. The first inductive element and the second resistive element are coupled in series between the output node and a first voltage supply node. The first variable capacitor is coupled between the input node and a first node located between the first inductive element and the second resistive element.

Abstract: A low power clock distribution circuit system (200) includes a clock generator (201) for generating a high frequency clock signal that is supplied to a clock interconnect running to multiple lanes of an integrated circuit, each lane including a passive clock repeater circuit (e.g., 203) having a differential-mode RLC network (e.g., 301) that is shielded by an active guard ring structure (e.g., 511) and that is coupled to receive first and second input clock signals (Vip, Vin) to provide clock signal gain boosting at a predetermined frequency range and clock signal attenuation out of the operating frequency range, thereby generating the first and second output clock signals (Vop, Von) that are provided to a clocked circuit (e.g., 211).

Abstract: A low power clock distribution circuit system (200) includes a clock generator (201) for generating a high frequency clock signal that is supplied to a clock interconnect running to multiple lanes of an integrated circuit, each lane including a passive clock repeater circuit (e.g., 203) having a differential-mode RLC network (e.g., 301) that is shielded by an active guard ring structure (e.g., 511) and that is coupled to receive first and second input clock signals (Vip, Vin) to provide clock signal gain boosting at a predetermined frequency range and clock signal attenuation out of the operating frequency range, thereby generating the first and second output clock signals (Vop, Von) that are provided to a clocked circuit (e.g., 211).

Abstract: An analog delay cell is provided that includes a transconductance-capacitance stage and an inductive transimpedance amplifier stage that provides an all-pass transfer function. In another embodiment, an adaptive analog delay cell including a transconductance (gm) plus capacitance (C) stage and an inductive-capacitance transimpedance amplifier (TIA) stage with digitally programmable phase-shift is provided. The adaptive analog delay cell increases the phase-shift by incorporating an LC network in the feedback path of the transimpedance stage. The disclosed analog delay cells can be used to provide delays in a tapped delay line. Also, the disclosed analog delay cells may be used to perform the multiplier and summation functions of a tapped delay line in addition to providing the delays. In another embodiment, the transimpedance amplifier stage includes an inductive-capacitive transimpedance amplifier stage.

Abstract: A connection interface switching device for multiple portable devices provides a communication channel between an I/O peripheral set and for a plurality of portable devices which are bundled with a default control program installed in the portable devices, and switches among the portable devices to establish a communication channel selected between one portable device and the I/O peripheral set according to a switch instruction generated by the default control program of the portable device. The connection interface switching device includes plural I/O ports, a controller, a memory module, a storage module and an I/O peripheral port, and an origin of the computer signal is controlled and switched to achieve the effect of sharing the same I/O peripheral set among multiple portable devices through the communication channel.

Abstract: A data sampler circuit comprises a transconductance amplifier, a latch circuit, a current-to-voltage converter, and a negative resistance circuit. The transconductance amplifier has an input and an output. The latch circuit is coupled to the output of the transconductance amplifier. The current-to-voltage converter has an input coupled to the output of the transconductance amplifier, and an output for providing a feedback signal to the latch circuit. The negative resistance circuit is coupled to the output of the transconductance amplifier and provides equalization during both a sampling mode and a data latching mode. In one embodiment, the negative resistance circuit comprises a pair of cross-coupled transistors. A gain of the negative resistance circuit can be adjusted based on a pulse width of an input signal.

Abstract: A continuous-time linear equalizer implementing enhanced analog delay cells with gain-peaking characteristics and a constant delay time. A receiver feed-forward equalizer architecture implements a gain-stage chain, analog multipliers for correcting coefficients, and a linear combiner as an analog summation circuit. Each of the gain stages produces linear gain peaking and presents a constant delay-time (through calibrations) at each stage. Each delay cell includes a transconductance stage configured to convert a differential input voltage signal to a differential output current signal, wherein the transconductance stage includes a differential pair of first and second transistors coupled in a source degeneration configuration, a negative resistance network coupled in parallel with a tunable resistor network, and shunt inductive circuitry coupled in parallel with the negative resistance network.

Abstract: A coaxial terminal crimping tool comprising a first rod body, a second rod body, a connecting rod, a sliding element, and a compensation block is disclosed. One end of the second rod body is connected to one end of the first rod body. One end of the connecting rod is connected with the first rod body. The sliding element is movably combined with the second rod body and is connected to another end of the connecting rod. The compensation block comprises a combining element, a first backup plate, and a second backup plate. The combining element is combined with another end of the second rod body; the first backup plate is pivotally connected with the combining element and comprises a first opening; the second backup plate is pivotally connected with the first backup plate and comprises a second opening having an aperture different from that of the first opening.

Abstract: A passive equalizer includes a first resistive element coupled between a first input node and a first output node, a first capacitive element, a first variable resistor, and a first inductive element coupled in series between the first input node and the first output node, a first transistor having a first current electrode coupled to the first output node, and a first current source coupled to the first current electrode of the first transistor.

Abstract: A CML latch includes an input stage including input nodes to receive a differential input signal and output nodes to provide a differential intermediate output signal, and a negative output node to provide a negative side of the differential intermediate output signal, a negative resistance stage including an input node connected to a first voltage source and output nodes connected to the output nodes of the input stage, and a latch stage including input nodes connected to the output nodes of the input stage and output nodes to provide a differential output signal. The negative resistance stage increases a current gain of the input stage.