Patent application number | Description | Published |
20120038405 | DELAY LINES, AMPLIFIER SYSTEMS, TRANSCONDUCTANCE COMPENSATING SYSTEMS AND METHODS OF COMPENSATING - Embodiments of delay lines may include a plurality of delay stages coupled to each other in series from a first stage to a last stage. Each delay stage may include an input transistor receiving a signal being delayed by the delay line. The delay line may include a compensating circuit configured to compensate for a change in a transconductance of the input transistor resulting from various factors. One such compensating circuit may be configured to provide a bias signal at an output node having a magnitude that is a function of a transconductance of a transistor in the compensating circuit. The bias signal may be used by each of the delay stages to maintain the gain of the respective delay stage substantially constant, such as a gain of substantially unity, despite changes in a transconductance of the respective input transistor in each of the delay stages. | 02-16-2012 |
20120086488 | DIFFERENTIAL AMPLIFIERS, CLOCK GENERATOR CIRCUITS, DELAY LINES AND METHODS - A differential amplifier may be configured to have a duty cycle and/or gain that is adjustable, such as by adjusting the switch points of circuitry in the differential amplifier. The differential amplifier may alternatively or additionally have a hysteresis function by, for example, using a signal feedback from the output of the amplifier to adjust the switch points of circuitry in the differential amplifier. The differential amplifier may be used for a variety of purposes, such as in an input buffer or delay line, either of which may be used, for example, in a clock generator circuit. | 04-12-2012 |
20120182057 | POWER SUPPLY INDUCED SIGNAL JITTER COMPENSATION - Examples of circuits and methods for compensating for power supply induced signal jitter in path elements sensitive to power supply variation. An example includes a signal path coupling an input to an output, the signal path including a delay element having a first delay and a bias-controlled delay element having a second delay. The first delay of the delay element exhibits a first response to changes in power applied thereto and the second delay of the bias-controlled delay element exhibits a second response to changes in the power applied such that the second response compensates at least in part for the first response. | 07-19-2012 |
20120249193 | MEASUREMENT INITIALIZATION CIRCUITRY - Measurement initialization circuitry is described. Propagation of a start signal through a variable delay line may be stopped by either of two stop signals. One stop signal corresponds to a rising edge of a reference clock signal. A second stop signal corresponds to a falling edge of the reference clock signal. The start signal propagation is stopped responsive to the first to arrive of the first and second stop signals. Accordingly, in some examples, start signal propagation through a variable delay line may be stopped responsive to either a rising or falling edge of the reference clock signal. | 10-04-2012 |
20120306554 | APPARATUS AND METHODS FOR ALTERING THE TIMING OF A CLOCK SIGNAL - Clock signal timing cells, clock signal timing circuits, clock circuits, memory devices, systems, and method for altering the timing of a clock signal are disclosed. An example method for altering the timing of an output signal provided responsive to an input clock signal includes adjusting a transition of an edge of the output signal from one voltage level to another based at least in part on a bias signal. An example clock signal timing cell includes an inverter and a bias controlled inverter coupled in parallel to the inverter. The bias controlled circuit is configured to provide an output signal wherein a transition of a clock edge of the output signal between first and second voltage levels is based at least in part on a bias signal. | 12-06-2012 |
20120326786 | DELAY LINES, AMPLIFIER SYSTEMS, TRANSCONDUCTANCE COMPENSATING SYSTEMS AND METHODS OF COMPENSATING - Embodiments of delay lines may include a plurality of delay stages coupled to each other in series from a first stage to a last stage. Each delay stage may include an input transistor receiving a signal being delayed by the delay line. The delay line may include a compensating circuit configured to compensate for a change in a transconductance of the input transistor resulting from various factors. One such compensating circuit may be configured to provide a bias signal at an output node having a magnitude that is a function of a transconductance of a transistor in the compensating circuit. The bias signal may be used by each of the delay stages to maintain the gain of the respective delay stage substantially constant, such as a gain of substantially unity, despite changes in a transconductance of the respective input transistor in each of the delay stages. | 12-27-2012 |
20130015899 | DELAY LINES, AMPLIFIER SYSTEMS, TRANSCONDUCTANCE COMPENSATING SYSTEMS AND METHODS OF COMPENSATING - Embodiments of delay lines may include a plurality of delay stages coupled to each other in series from a first stage to a last stage. Each delay stage may include an input transistor receiving a signal being delayed by the delay line. The delay line may include a compensating circuit configured to compensate for a change in a transconductance of the input transistor resulting from various factors. One such compensating circuit may be configured to provide a bias signal at an output node having a magnitude that is a function of a transconductance of a transistor in the compensating circuit. The bias signal may be used by each of the delay stages to maintain the gain of the respective delay stage substantially constant, such as a gain of substantially unity, despite changes in a transconductance of the respective input transistor in each of the delay stages. | 01-17-2013 |
20130193986 | DELAY LINE SCHEME WITH NO EXIT TREE - A measure initialization path for a delay line structure includes: a forward path, comprising a plurality of delay stages coupled in series; a first output path coupled to at least an output of a delay stage of the forward path, where at least an output of a delay stage is fed forward to the forward path; and a second output path coupled to at least an output of a delay stage of the forward path, where at least an output of a delay stage is fed forward to the forward path. When a signal is propagated through the measure initialization path, the signal successively propagates through a delay stage of the forward path, a delay stage of the first output path and a delay stage of the second output path for performing measure initialization. | 08-01-2013 |
20130241619 | POWER SUPPLY INDUCED SIGNAL JITTER COMPENSATION - Examples of circuits and methods for compensating for power supply induced signal jitter in path elements sensitive to power supply variation. An example includes a signal path coupling an input to an output, the signal path including a delay element having a first delay and a bias-controlled delay element having a second delay. The first delay of the delay element exhibits a first response to changes in power applied thereto and the second delay of the bias-controlled delay element exhibits a second response to changes in the power applied such that the second response compensates at least in part for the first response. | 09-19-2013 |
20140097880 | MEASUREMENT INITIALIZATION CIRCUITRY - Measurement initialization circuitry is described. Propagation of a start signal through a variable delay line may be stopped by either of two stop signals. One stop signal corresponds to a rising edge of a reference clock signal. A second stop signal corresponds to a falling edge of the reference clock signal. The start signal propagation is stopped responsive to the first to arrive of the first and second stop signals. Accordingly, in some examples, start signal propagation through a variable delay line may be stopped responsive to either a rising or falling edge of the reference clock signal. | 04-10-2014 |
20140119133 | CLOCK SIGNAL GENERATORS HAVING A REDUCED POWER FEEDBACK CLOCK PATH AND METHODS FOR GENERATING CLOCKS - Memories, clock generators and methods for providing an output clock signal are disclosed. One such method includes delaying a buffered clock signal by an adjustable delay to provide an output clock signal, providing a feedback clock signal from the output clock signal, and adjusting a duty cycle of the buffered clock signal based at least in part on the feedback clock signal. An example clock generator includes a forward clock path configured to provide a delayed output clock signal from a clock driver circuit, and further includes a feedback clock path configured to provide a feedback clock signal based at least in part on the delayed output clock signal, for example, frequency dividing the delayed output clock signal. The feedback clock path further configured to control adjustment a duty cycle of the buffered input clock signal based at least in part on the feedback clock signal. | 05-01-2014 |
20140152361 | APPARATUS AND METHODS FOR ALTERING THE TIMING OF A CLOCK SIGNAL - Clock signal timing cells, clock signal timing circuits, clock circuits, memory devices, systems, and method for altering the timing of a clock signal are disclosed. An example method for altering the timing of an output signal provided responsive to an input clock signal includes adjusting a transition of an edge of the output signal from one voltage level to another based at least in part on a bias signal. An example clock signal timing cell includes an inverter and a bias controlled inverter coupled in parallel to the inverter. The bias controlled circuit is configured to provide an output signal wherein a transition of a clock edge of the output signal between first and second voltage levels is based at least in part on a bias signal. | 06-05-2014 |
20140253193 | DIFFERENTIAL AMPLIFIERS, CLOCK GENERATOR CIRCUITS, DELAY LINES AND METHODS - A differential amplifier may be configured to have a duty cycle and/or gain that is adjustable, such as by adjusting the switch points of circuitry in the differential amplifier. The differential amplifier may alternatively or additionally have a hysteresis function by, for example, using a signal feedback from the output of the amplifier to adjust the switch points of circuitry in the differential amplifier. The differential amplifier may be used for a variety of purposes, such as in an input buffer or delay line, either of which may be used, for example, in a clock generator circuit. | 09-11-2014 |
20140320190 | POWER SUPPLY INDUCED SIGNAL JITTER COMPENSATION - Examples of circuits and methods for compensating for power supply induced signal jitter in path elements sensitive to power supply variation. An example includes a signal path coupling an input to an output, the signal path including a delay element having a first delay and a bias-controlled delay element having a second delay. The first delay of the delay element exhibits a first response to changes in power applied thereto and the second delay of the bias-controlled delay element exhibits a second response to changes in the power applied such that the second response compensates at least in part for the first response. | 10-30-2014 |
20140340069 | CURRENT GENERATOR CIRCUIT AND METHODS FOR PROVIDING AN OUTPUT CURRENT - Current circuits, circuits configured to provide a bias voltage, and methods for providing a bias voltage are described, including a current circuit configured to receive a reference current and having an output at which an output current is provided. One such current circuit includes a first current mirror configured to receive a first portion of the reference current and further configured to mirror the first portion of the reference current to provide a first current. The current circuit further includes a second current mirror configured to receive a second portion of the reference current and receive the first current. The second current mirror is further configured to provide a portion of the first current to the output of the current circuit as the output current and to receive another portion of the first current and mirror the same as the second portion of the reference current. | 11-20-2014 |
20140375366 | MEASUREMENT INITIALIZATION CIRCUITRY - Measurement initialization circuitry is described. Propagation of a start signal through a variable delay line may be stopped by either of two stop signals. One stop signal corresponds to a rising edge of a reference clock signal. A second stop signal corresponds to a falling edge of the reference clock signal. The start signal propagation is stopped responsive to the first to arrive of the first and second stop signals. Accordingly, in some examples, start signal propagation through a variable delay line may be stopped responsive to either a rising or falling edge of the reference clock signal. | 12-25-2014 |