Abstract: A PLL includes control circuitry adapted to detect missing pulses of a reference clock and to control an output voltage of a charge pump disposed in the PLL accordingly. A signal generated in response to the detection of a missing pulse is pulse-width limited and applied to the charge pump during a first period. The detection of the pulse-width limited signal is used to generate a first slew signal that is also pulse-width limited and applied to the charge pump during a second period. The detection of the first slew signal is used to generate a second slew signal that is also pulse-width limited and applied to the charge pump during a third period. The amount of current supplied by the charge pump during the second charging period is equal to a sum of currents withdrawn by the charge pump during the first and third time periods.

Abstract: A phase/frequency locked loop (PLL) includes circuitry adapted to detect missing pulses of a reference clock and to control the phase bump of the PLL. The circuitry includes, in part, first and second flip-flops, as well as a one-shot block. The first flip-flop has a data input terminal responsive to a voltage supply, and a clock terminal responsive to an inverse of feedback clock. The second flip-flop has a data input terminal responsive to an output of the first flip-flop, and a clock terminal responsive to the inverse of the feedback clock. The one-shot block generates a pulse in response to a rising edge of the reference clock that is used to generate the feedback clock. The one-shot block generates an output signal applied to a reset terminal of the first flip-flop.

Abstract: A phase/frequency locked loop (PLL) includes circuitry adapted to detect missing pulses of a reference clock and to control the phase bump of the PLL. The circuitry includes, in part, first and second flip-flops, as well as a one-shot block. The first flip-flop has a data input terminal responsive to a voltage supply, and a clock terminal responsive to an inverse of feedback clock. The second flip-flop has a data input terminal responsive to an output of the first flip-flop, and a clock terminal responsive to the inverse of the feedback clock. The one-shot block generates a pulse in response to a rising edge of the reference clock that is used to generate the feedback clock. The one-shot block generates an output signal applied to a reset terminal of the first flip-flop.

Abstract: A phase/frequency locked loop (PLL) includes circuitry adapted to detect missing pulses of a reference clock and to control the phase bump of the PLL. The circuitry includes, in part, first and second flip-flops, as well as a one-shot block. The first flip-flop has a data input terminal responsive to a voltage supply, and a clock terminal responsive to an inverse of feedback clock. The second flip-flop has a data input terminal responsive to an output of the first flip-flop, and a clock terminal responsive to the inverse of the feedback clock. The one-shot block generates a pulse in response to a rising edge of the reference clock that is used to generate the feedback clock. The one-shot block generates an output signal applied to a reset terminal of the first flip-flop.

Abstract: A PLL includes control circuitry adapted to detect missing pulses of a reference clock and to control an output voltage of a charge pump disposed in the PLL accordingly. A signal generated in response to the detection of a missing pulse is pulse-width limited and applied to the charge pump during a first period. The detection of the pulse-width limited signal is used to generate a first slew signal that is also pulse-width limited and applied to the charge pump during a second period. The detection of the first slew signal is used to generate a second slew signal that is also pulse-width limited and applied to the charge pump during a third period. The amount of current supplied by the charge pump during the second charging period is equal to a sum of currents withdrawn by the charge pump during the first and third time periods.

Abstract: A charge pump includes a multitude of current sources and current sinks adapted to supply current to or discharge current from a loop filter. The paths between current sources/sinks and the loop filter are selectively activated or deactivated to enable current to flow from the current source(s) to the loop filter or flow from the loop filter to the current sinks(s). Accordingly, the charge pump is adapted to provide more than one bandwidth depending on the bit levels of a select signal. The slew rate of a PLL in which the charge pump is disposed may thus be reduced. The charge pump optionally includes pulse-width limiting circuitry to limit the width of the pulses received from a phase/frequency detector. Accordingly, the slew rate of the PLL may further be reduced without changes in the open loop characteristics or losses in the phase margin.

Abstract: A charge pump includes a multitude of current sources and current sinks adapted to supply current to or discharge current from a loop filter. The paths between current sources/sinks and the loop filter are selectively activated or deactivated to enable current to flow from the current source(s) to the loop filter or flow from the loop filter to the current sinks(s). Accordingly, the charge pump is adapted to provide more than one bandwidth depending on the bit levels of a select signal. The slew rate of a PLL in which the charge pump is disposed may thus be reduced. The charge pump optionally includes pulse-width limiting circuitry to limit the width of the pulses received from a phase/frequency detector. Accordingly, the slew rate of the PLL may further be reduced without changes in the open loop characteristics or losses in the phase margin.

Abstract: A method, system and computer program product for transformation, normalization and correlation techniques that are effective for matching names of foreign origin that may be spelt in any number of ways. It addresses the problem of matching names that may belong to the same person but may be spelt differently. The main technique is to convert both strings to be matched into a representation of their original language, i.e., transform them into idealized (normalized) versions of themselves based on their true spelling in their original, native language. This process of idealization can be done either by employing a dictionary of standard, idealized names, or by implementing the idealization in real time by following a finite-state algorithm to convert the strings into their true representation in their original language.