Abstract: An apparatus includes an oscillator circuit, a counter circuit, and a control circuit. The oscillator circuit may receive an input clock signal and an inverse input clock signal, and, for a first time period, may generate an oscillator output signal with a frequency based on a duty cycle of the input clock signal. For a second time period, the oscillator circuit may generate the oscillator output signal with a frequency based on a duty cycle of the inverse input clock signal. The counter circuit may count oscillations of the oscillator output signal over the first time period and over the second time period. The control circuit may determine, based on the oscillations counted by the counter circuit during the first time period and the second time period, a duty cycle value indicative of the duty cycle of the input clock signal.

Abstract: An apparatus includes an oscillator circuit, a counter circuit, and a control circuit. The oscillator circuit may receive an input clock signal and an inverse input clock signal, and, for a first time period, may generate an oscillator output signal with a frequency based on a duty cycle of the input clock signal. For a second time period, the oscillator circuit may generate the oscillator output signal with a frequency based on a duty cycle of the inverse input clock signal. The counter circuit may count oscillations of the oscillator output signal over the first time period and over the second time period. The control circuit may determine, based on the oscillations counted by the counter circuit during the first time period and the second time period, a duty cycle value indicative of the duty cycle of the input clock signal.

Abstract: A calibration and adjustment system for post-fabrication control of a delay locked loop bias-generator is provided. The calibration and adjustment system includes an adjustment circuit operatively connected to the bias-generator, where the adjustment circuit is controllable to facilitate a modification of a voltage output by the bias-generator. Such control of the voltage output by the bias-generator allows a designer to achieve a desired delay locked loop performance characteristic after the delay locked loop has been fabricated. A representative value of the amount of adjustment desired in the bias-generator output may be stored and subsequently read to adjust the delay locked loop.

Abstract: An adjustment and calibration system for post-fabrication treatment of a phase locked loop input receiver is provided. The adjustment and calibration system includes at least one adjustment circuit, to which the phase locked loop input receiver is responsive, and a storage device that selectively stores control information (1) associated with a state of the adjustment circuit and/or (2) from a tester that writes such control information to the storage device, where the control information stored in the storage device is subsequently selectively read out in order to adjust the adjustment circuit to a state corresponding to the control information.

Abstract: A method and apparatus for post-fabrication calibration and adjustment of a phase locked loop leakage current is provided. The calibration and adjustment system includes an adjustment circuit that adjusts a leakage current offset circuit to compensate for the leakage current of a capacitor. The capacitor connects to a control voltage of the phase locked loop. Such control of the leakage current in the phase locked loop allows a designer to achieve a desired phase locked loop operating characteristic after the phase locked loop has been fabricated. A representative value of the amount of compensation desired in the leakage current may be stored and subsequently read to adjust the phase locked loop.

Abstract: A method and apparatus for assigning a set of region-based voltage drop budgets to an integrated circuit is provided. Further, a method for partitioning an integrated circuit into optimal voltage drop regions includes analyzing the integrated circuit for worst-case voltage drop data. The worst-case voltage drop data is used to partition the integrated circuit into a set of voltage drop regions, wherein each voltage drop region is assigned a region-based voltage drop budget. The region-based voltage drop budget assigned to a particular voltage drop region is based on a worst-case voltage drop experienced by that voltage drop region.

Abstract: A method and apparatus for improving the timing accuracy of an integrated circuit through region-based voltage drop budgets is provided. Further, a method for performing timing analysis on an integrated circuit partitioned into voltage drop regions is provided. During the timing analysis, a set of logic paths segments in each voltage drop region is tested to ensure that the integrated circuit meets a set of predefined timing requirements. Logic path segments that reside in different voltage drop regions are tested using a supply voltage inputted by the respective voltage drop region.

Abstract: A system and method of determining an in-situ signal path delay on an integrated circuit. The system and method includes inputting a first signal to a first input node of a first signal path and inputting a second signal to a second input node of a reference signal path. A phase of the first signal output from a first output node of the first signal path is compared to a phase of the second signal output from a second output node of the reference signal path. A phase error signal is output.

Abstract: A method and apparatus for compensating for age related degradation in the performance of integrated circuits. In one embodiment, the phase-locked loop (PLL) charge pump is provided with multiple legs that can be selectively enabled or disabled to compensate for the effects of aging. In an alternate embodiment, the power supply voltage control codes can be increased or decreased to compensate for aging effects. In another embodiment, a ring oscillator is used to approximate the effects of NBTI. In this embodiment, the frequency domain is converted to time domain using digital counters and programmable power supply control words are used to change the operating parameters of the power supply to compensate for aging effects.

Abstract: A device that uses an input clock signal to generate an output clock signal with a desired frequency is provided. The device uses a voltage controlled delay element that outputs a reset signal to a flip-flop dependent on a bias signal and the input clock signal. When triggered, the flip-flop outputs a transition on the output clock signal, which, in turn, serves as an input to a duty cycle corrector that generates the bias signal dependent on the configuration of the duty cycle corrector. The duty cycle corrector may be configured to generate the bias signal so as to be able to operatively control the duty cycle of the output clock signal.

Abstract: A phase locked loop design uses a diode operatively connected to a loop filter capacitor to control a leakage current of the loop filter capacitor. By positioning a diode in series with the loop filter capacitor, a voltage potential across the loop filter capacitor is reduced, thereby reducing the leakage current of the loop filter capacitor. Moreover, the leakage current of the loop filter capacitor is controlled in that it cannot exceed the current through the diode. Control and reduction of the loop filter capacitor leakage current leads to more reliable and stable phase locked loop behavior.

Abstract: A self-correcting I/O interface driver scheme uses a delay difference detector to detect a difference in delays between an I/O data path and an I/O clock path. The delay difference detector inputs signals from a data output pin connected to the I/O data path and a clock output pin connected to the I/O clock path. Upon determining a delay difference between the signals from the data and clock output pins, the delay difference detector generates signals to one or more drivers in the I/O data path and the I/O clock path. These signals from the delay difference detector are used to effectively adjust delays of the one or more drivers in order to effectively reduce the delay difference between the I/O data path and the I/O clock path.

Abstract: A self-correcting I/O interface driver scheme uses a delay difference detector to detect a difference in delays between an I/O data path and an I/O clock path. The delay difference detector inputs signals from a data output pin connected to the I/O data path and a clock output pin connected to the I/O clock path. Upon determining a delay difference between the signals from the data and clock output pins, the delay difference detector generates signals to one or more drivers in the I/O data path and the I/O clock path. These signals from the delay difference detector are used to effectively adjust delays of the one or more drivers in order to effectively reduce the delay difference between the I/O data path and the I/O clock path.

Abstract: A method for estimating jitter in a phase locked loop is provided. The estimation is determined from a simulation that uses a representative power supply waveform having noise as an input. Further, a computer system for estimating jitter in a phase locked loop is provided. Further, a computer-readable medium having recorded thereon instructions adapted to estimate jitter in a phase locked loop is provided.

Abstract: An apparatus that uses a linear voltage regulator to reject power supply noise in a temperature sensor is provided. Further, a method for using a linear voltage regulator to reject power supply noise in a temperature sensor is provided. Further, a method and apparatus that uses a differential amplifier with a source-follower output stage as a linear voltage regulator for a temperature sensor is provided.

Abstract: A method and apparatus that uses the difference between two nodal voltages, such as a temperature-independent voltage and a temperature-dependent voltage, to determine the actual temperature at a point on an integrated circuit is provided. Further, a method and apparatus that converts a difference between nodal voltages in an integrated circuit from an analog to a digital quantity on the integrated circuit such that the difference in voltage may be used by an on-chip digital system is provided. Further, a method and apparatus for quantifying a difference in voltage between a first node and a second node of a temperature sensor is provided.

Abstract: A system and method of determining an in-situ signal path delay on an integrated circuit. The system and method includes inputting a first signal to a first input node of a first signal path and inputting a second signal to a second input node of a reference signal path. A phase of the first signal output from a first output node of the first signal path is compared to a phase of the second signal output from a second output node of the reference signal path. A phase error signal is output.

Abstract: A calibration and adjustment system for post-fabrication control of a delay locked loop charge pump current is provided. The calibration and adjustment system includes an adjustment device that varies an amount of charge pump current. Such control of the charge pump current in a delay locked loop allows a designer to achieve a desired delay locked loop operating characteristic after the delay locked loop has been fabricated. A representative value of the amount of adjustment desired in the charge pump current may be stored and subsequently read to adjust the delay locked loop.

Abstract: A phase locked loop that includes a receiver that is adjustable to substantially match delay of a system clock and a feedback clock at an input of the phase locked loop is provided. The receiver employs system clock path circuitry to input the system clock and feedback clock path circuitry to input the feedback clock, where current flow and load resistances associated with the system clock path circuitry and current flow and load resistances associated with the feedback clock path circuitry are responsive to one or more bias signals that are adjustable using one or more adjustment circuits that are operatively connected to the receiver. The control of the one or more bias signals via the one or more adjustment circuits facilitates the generation of substantially delay matched system and feedback clocks.

Abstract: A negative impedance device that accelerates signal transitions on a signal is provided. The negative impedance device is highly responsive to high to low and low to high transitions on the signal, and when one of these types of transitions begins to occur on the signal, the negative impedance device senses the transition and quickly drives the signal to the intended value before a point in time when the signal would have reached the intended value had the negative impedance device not been used. Further, a signal transition accelerator design that reduces signal rise and fall times is provided. Further, a method for accelerating a signal transition is provided.