Patent application number | Description | Published |
20100013531 | PHASE-LOCKED LOOP CIRCUITS AND METHODS IMPLEMENTING PULSEWIDTH MODULATION FOR FINE TUNING CONTROL OF DIGITALLY CONTROLLED OSCILLATORS - PLL (phase locked loop) circuits and methods are provided in which PWM (pulse width modulation) techniques are to achieve continuous fine tuning control of DCO (digitally controlled oscillator) circuits. In general, pulse width modulation techniques are applied to further modulate dithered control signals that are used to enhance the frequency tuning resolution of the DCO such that the dithered control signals are applied to the fractional tracking control port of the DCO for a selected fraction of a full clock signal based pulse width modulation applied. | 01-21-2010 |
20100013532 | PHASE-LOCKED LOOP CIRCUITS AND METHODS IMPLEMENTING MULTIPLEXER CIRCUIT FOR FINE TUNING CONTROL OF DIGITALLY CONTROLLED OSCILLATORS - Circuits and methods are provided in which fine tuning control of a DCO (digitally controlled oscillator) circuit in a digital PLL circuit is realized by dither controlling a multiplexer circuit under digital control to selectively output one of a plurality of analog control voltages with varied voltage levels that are input to a fractional frequency control port of the DCO to drive tuning elements of the DCO at fractional frequency resolution and achieve continuous fine tuning of the DCO under analog control. | 01-21-2010 |
20100188158 | OPTIMAL DITHERING OF A DIGITALLY CONTROLLED OSCILLATOR WITH CLOCK DITHERING FOR GAIN AND BANDWIDTH CONTROL - A digital phase locked loop (DPLL) and method include an adjustable delay line configured to receive a reference clock as an input and to output a dithered reference clock signal. A phase and frequency detector (PFD) is configured to compare the dithered reference clock signal with a feedback clock signal to determine phase and frequency differences between the dithered reference clock signal and the feedback clock signal. A digitally controlled oscillator (DCO) is configured to receive early or late determinations from the PFD to adjust an output in accordance therewith, wherein the dithered reference clock signal distributes jitter response to enhance overall operation of the DPLL. | 07-29-2010 |
20130076449 | VARACTOR TUNING CONTROL USING REDUNDANT NUMBERING - Techniques for improved tuning control of varactor circuits are disclosed. For example, an apparatus comprises a plurality of varactors for tuning a frequency value. The plurality of varactors comprises approximately sqrt(2N) varactors, where N is a number of tunings steps and the plurality of varactors are respectively sized as 1x, 2x, 3x, 4x, . . . , approximately sqrt(2N)x, and where x is a unit of capacitance. A given one of the N tuning steps may be represented by more than one combination of varactors. This may be referred to as redundant numbering. | 03-28-2013 |
20130278285 | MINIMUM-SPACING CIRCUIT DESIGN AND LAYOUT FOR PICA - PICA test circuits are shown that include a first transistor and a second transistor laid out drain-to-drain, such that a gap between respective drain regions of the first and second transistors has a minimum size allowed by a given fabrication technology; a first NOR gate having an output connected to the drain region of the first transistor and accepting a first select signal and an input signal; and a second NOR gate having an output connected to the drain region of the second transistor and accepting a second select signal and the input signal. One of said NOR gates biases the connected transistor's drain region, according to the select signal of said NOR gate, to inhibit an optical emission when said connected transistor is triggered. | 10-24-2013 |
20130280828 | MINIMUM-SPACING CIRCUIT DESIGN AND LAYOUT FOR PICA - PICA test methods are shown that includes forming semiconductor devices having proximal light emitting regions, such that the light emitting regions are grouped into distinct shapes separated by a distance governed by a target resolution size; forming logic circuits to control the semiconductor devices; activating the one or more semiconductor devices by providing an input signal; and suppressing light emissions from one or more of the activated semiconductor devices by providing one or more select signals to the logic circuits. | 10-24-2013 |
20140070855 | HYBRID PHASE-LOCKED LOOP ARCHITECTURES - Phase locked loop (PLL) architectures are provided such as hybrid PLL architectures having separate digital integrating control paths and analog proportional control paths. An analog proportional control path can be implemented with a charge pump circuit that includes resistors in series with CMOS switches to generate control currents (e.g., Up/Down control currents) which are used to adjust a control voltage applied to a digitally controlled oscillator. A digital integrating control path can be implemented with a series of sigma-delta modulators that operate at different frequencies to convert higher bit data signals to lower bit data signals along the digital integrating control path. A single phase frequency detector may be implemented to generate control signals that separately control the analog proportional and digital integrating control paths. | 03-13-2014 |
20140070856 | HYBRID PHASE-LOCKED LOOP ARCHITECTURES - Phase locked loop (PLL) architectures are provided such as hybrid PLL architectures having separate digital integrating control paths and analog proportional control paths. An analog proportional control path can be implemented with a charge pump circuit that includes resistors in series with CMOS switches to generate control currents (e.g., Up/Down control currents) which are used to adjust a control voltage applied to a digitally controlled oscillator. A digital integrating control path can be implemented with a series of sigma-delta modulators that operate at different frequencies to convert higher bit data signals to lower bit data signals along the digital integrating control path. A single phase frequency detector may be implemented to generate control signals that separately control the analog proportional and digital integrating control paths. | 03-13-2014 |
20140176183 | MINIMUM-SPACING CIRCUIT DESIGN AND LAYOUT FOR PICA - PICA test circuits are shown that include a first transistor and a second transistor laid out drain-to-drain, such that a gap between respective drain regions of the first and second transistors has a minimum size allowed by a given fabrication technology. | 06-26-2014 |
20140184439 | SCALABLE POLARIMETRIC PHASED ARRAY TRANSCEIVER - A polarimetric transceiver front-end includes two receive paths configured to receive signals from an antenna, each receive path corresponding to a respective polarization. Each front-end includes a variable amplifier and a variable phase shifter; a first transmit path configured to send signals to the antenna, where the transmit path is connected to the variable phase shifter of one of the two receive paths and includes a variable amplifier; and a transmit/receive switch configured to select between the first transmit path and the two receive paths for signals, where the transmit/receive switch includes a quarter-wavelength transmission line that adds a high impedance to the transmit path when the transmit/receive switch is in a receiving state. | 07-03-2014 |
20140191816 | DESIGN STRUCTURE FOR AN INDUCTOR-CAPACITOR VOLTAGE-CONTROLLED OSCILLATOR - Embodiments of the present invention provide a design structure and method for compensating for a change in frequency of oscillation (FOO) of an LC-tank VCO that includes a first node; second node; inductor; first capacitive network (FCN) that allows the design structure to obtain a target FOO; compensating capacitive (CCN) network that compensates for a change in the design structure's FOO; second capacitive network (SCN) that allows the design structure to obtain a desired FOO; a filter that supplies a voltage to the SCN and is coupled to the SCN; a transconductor that compensates for a change in the design structure's FOO; and a sub-circuit coupled to the SCN that generates and supplies voltage to the CCN sufficient to allow the CCN to compensate for a reduction in the design structure's FOO. The first and second nodes are coupled to the inductor, FCN, CCN, SCN, and sub-circuit. | 07-10-2014 |