Patent application number | Description | Published |
20080238630 | SYSTEM AND METHOD FOR VARYING RESPONSE AMPLITUDE OF RADIO TRANSPONDERS - A system and method are provided for modifying the effective reading range of an radio frequency identification tag. The tag, a chip based tag, includes an antenna and a chip in communication with the antenna. The chip includes circuitry including field effect transistors that can modify the effective reading range of the tag by modifying characteristics of the tag including the modulation depth of the backscatter signal, the impedance characteristics of the tag front end electronics, the power consumption characteristics and the threshold power-on voltage of the tag. These characteristics are change either temporarily or permanently in response to commands communicated to the tag from a radio frequency identification reader. | 10-02-2008 |
20080298530 | DATA-DEPENDENT JITTER PRE-EMPHASIS FOR HIGH-SPEED SERIAL LINK TRANSMITTERS - In the context of high-speed serial links, data-dependent jitter compensation techniques performed using phase pre-distortion. Broadly contemplated is an expansion of the notion of pre-emphasis beyond conventional amplitude compensation of ISI, whereby phase pre-emphasis for compensating data-dependent jitter (DDJ) is introduced. DDJ can be addressed by exploiting the relationship between the data sequence and the timing deviation. Phase pre-emphasis improves the signal integrity with little additional power consumption in the transmitter and with no cross-talk penalty. | 12-04-2008 |
20080310495 | DECISION FEEDBACK EQUALIZER USING SOFT DECISIONS - A decision feedback equalizer (DFE) and method include at least two paths. Each path includes the following. An adder is configured to sum an input with a first feedback tap fed back from a different path. A latch is coupled to the adder to receive a summation signal as input. The latch includes a transparent state, and an output of the latch is employed as the first tap in a feedback path to an adder of a different path, wherein a partially resolved first tap in the feedback path is employed during the transparent state to provide a soft decision to supply correction information in advance of a hard decision of the latch. | 12-18-2008 |
20090252215 | SAMPLED CURRENT-INTEGRATING DECISION FEEDBACK EQUALIZER AND METHOD - A decision feedback equalizer (DFE) and method including a branch coupled to an input and including a sample-and-hold element configured to receive and sample a received input signal from the input and a current-integrating summer. The current-integrating summer is coupled to an output of the sample-and-hold element. The summer is configured to receive and sum currents representing at least one previous decision and an input sample. The at least one previous decision and the input sample are integrated onto a node, wherein the input sample is held constant during an integration period, thereby mitigating the effects of input transitions on an output of the summer. | 10-08-2009 |
20090273405 | ARCHITECTURE FOR MAINTAINING CONSTANT VOLTAGE-CONTROLLED OSCILLATOR GAIN - A voltage controlled oscillator and a method of operating a voltage-controlled oscillator are disclosed. The oscillator comprises a current controlled oscillator having a variable frequency current output, a first control path for generating a first control current having a first adjustable gain, and a second control path for generating a second control current having a second adjustable gain. A summer is provided for adding the first and second control currents to obtain a summed control current, and for applying the summed control current as an input current to the current controlled oscillator. A control sub-circuit is used for controlling the gain of the first control current as a function of a defined voltage on the second control path to maintain constant the gain of the current output of the current controlled oscillator over a given operating range of the current controlled oscillator. | 11-05-2009 |
20090302905 | METHOD AND APPARATUS FOR ON-CHIP PHASE ERROR MEASUREMENT TO DETERMINE JITTER IN PHASE-LOCKED LOOPS - An apparatus includes a phase-locked loop (PLL) circuit including a phase-frequency detector configured to output phase error signals. A phase error monitor circuit is configured to determine instantaneous peak phase error by logically combining the phase error signals and comparing pulse widths of the logically combined phase error signals to a programmable delay time at each reference clock cycle to determine instantaneous phase error change. A storage element is configured to store the instantaneous phase error change. | 12-10-2009 |
20090302906 | METHOD AND APPARATUS FOR ON-CHIP PHASE ERROR MEASUREMENT TO DETERMINE JITTER IN PHASE-LOCKED LOOPS - An apparatus includes a phase-locked loop (PLL) circuit including a phase-frequency detector configured to output phase error signals. A phase error monitor circuit is configured to determine instantaneous peak phase error by logically combining the phase error signals and comparing pulse widths of the logically combined phase error signals to a programmable delay time at each reference clock cycle to determine instantaneous phase error change. A storage element is configured to store the instantaneous phase error change. | 12-10-2009 |
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 |
20100214078 | System and Method for Varying Response Amplitude of Radio Transponders - A system and method are provided for modifying the effective reading range of an radio frequency identification tag. The tag, a chip-based tag, includes an antenna and a chip in communication with the antenna. The chip includes circuitry including field effect transistors that can modify the effective reading range of the tag by modifying characteristics of the tag including the modulation depth of the backscatter signal, the impedance characteristics of the tag front end electronics, the power consumption characteristics and the threshold power-on voltage of the tag. These characteristics are change either temporarily or permanently in response to commands communicated to the tag from a radio frequency identification reader. | 08-26-2010 |
20110063003 | PHASE AND FREQUENCY DETECTOR WITH OUTPUT PROPORTIONAL TO FREQUENCY DIFFERENCE - Phase and frequency detectors and techniques are disclosed. For example, apparatus comprises a first circuit for receiving first and second clock signals and for generating at least one signal indicative of a phase difference between the first and second clock signals. The apparatus also comprises a second circuit for receiving the at least one signal generated by the first circuit and, in response to the at least one received signal, generating at least one output signal, wherein a frequency associated with the at least one output signal is proportional to a frequency difference between the first and second clock signals. | 03-17-2011 |
20110278155 | ELECTROCHEMICAL CONTROL OF CHEMICAL CATALYSIS USING SINGLE MOLECULE MOTORS AND DIGITAL LOGIC - Methods for controlling catalysis of a chemical reaction generally includes electrostatically controlling position of a first linear single-molecule polymer inside at least one nanopore fluidly coupled to a reaction chamber comprising a reaction medium and at least one reactant, wherein the first linear single-molecule polymer is coupled to a first catalyst at one end and includes one or more charged sub-units; and creating an electrostatic potential well inside the nanopore, wherein the electrostatic potential well controls a position of the first linear single-molecule polymer inside the at least one nanopore. Also disclosed are apparatuses for controlling catalysis of the chemical reaction. | 11-17-2011 |
20120084241 | PRODUCING SPIKE-TIMING DEPENDENT PLASTICITY IN A NEUROMORPHIC NETWORK UTILIZING PHASE CHANGE SYNAPTIC DEVICES - Embodiments of the invention relate to a neuromorphic network for producing spike-timing dependent plasticity. The neuromorphic network includes a plurality of electronic neurons and an interconnect circuit coupled for interconnecting the plurality of electronic neurons. The interconnect circuit includes plural synaptic devices for interconnecting the electronic neurons via axon paths, dendrite paths and membrane paths. Each synaptic device includes a variable state resistor and a transistor device with a gate terminal, a source terminal and a drain terminal, wherein the drain terminal is connected in series with a first terminal of the variable state resistor. The source terminal of the transistor device is connected to an axon path, the gate terminal of the transistor device is connected to a membrane path and a second terminal of the variable state resistor is connected to a dendrite path, such that each synaptic device is coupled between a first axon path and a first dendrite path, and between a first membrane path and said first dendrite path. | 04-05-2012 |
20120153909 | HYBRID FAST-SLOW PASSGATE CONTROL METHODS FOR VOLTAGE REGULATORS EMPLOYING HIGH SPEED COMPARATORS - Voltage regulator circuits and methods implementing hybrid fast-slow passgate control circuitry are provided to minimize the ripple amplitude of a regulated voltage output. In one aspect, a voltage regulator circuit includes a comparator, a first passgate device, a second passgate device, and a bandwidth limiting control circuit. The comparator compares a reference voltage to a regulated voltage at an output node of the voltage regulator circuit and generates a first control signal on a first gate control path based on a result of the comparing. The first and second passgate devices are connected to the output node of the regulator circuit. The first passgate device is controlled in a bang-bang mode of operation by the first control signal to supply current to the output node. The bandwidth limiting control circuit has an input connected to the first gate control path and an output connected to the second passgate device. The bandwidth limiting control circuit generates a second control signal based on the first control signal, wherein the second control signal is a slew rate limited version of the first control signal, and wherein the second passgate is controlled by the second control signal to supply current to the output node. | 06-21-2012 |
20120153910 | DUAL-LOOP VOLTAGE REGULATOR ARCHITECTURE WITH HIGH DC ACCURACY AND FAST RESPONSE TIME - Dual-loop voltage regulator circuits and methods in which a dual-loop voltage regulation framework is implemented with a first inner loop having a bang-bang voltage regulator to achieve nearly instantaneous response time, and a second outer loop, which is slower in operating speed than the first inner loop, to controllably adjust a trip point of the bang-bang voltage regulator to achieve high DC accuracy. | 06-21-2012 |
20120242383 | PHASE PROFILE GENERATOR - Phase profile generator systems and methods are disclosed. A system includes a signal generator, a target phase trajectory module, an error detector and a control loop filter. The signal generator is configured to generate an output signal. In addition, the target phase trajectory module is configured to track a target phase trajectory and determine a next adjustment of the output signal to conform the output signal to a portion of the target phase trajectory. Further, the error detector is configured to determine an error between the output signal and a current target phase trajectory value that precedes the portion of the target phase trajectory, where the determination of the error is independent of the next adjustment of the output signal. Moreover, the control loop filter is configured to control the signal generator in accordance with both the next adjustment and the error to generate a phase profile. | 09-27-2012 |
20120259804 | RECONFIGURABLE AND CUSTOMIZABLE GENERAL-PURPOSE CIRCUITS FOR NEURAL NETWORKS - A reconfigurable neural network circuit is provided. The reconfigurable neural network circuit comprises an electronic synapse array including multiple synapses interconnecting a plurality of digital electronic neurons. Each neuron comprises an integrator that integrates input spikes and generates a signal when the integrated inputs exceed a threshold. The circuit further comprises a control module for reconfiguring the synapse array. The control module comprises a global final state machine that controls timing for operation of the circuit, and a priority encoder that allows spiking neurons to sequentially access the synapse array. | 10-11-2012 |
20120314721 | TIMING RECOVERY METHOD AND APPARATUS FOR AN INPUT/OUTPUT BUS WITH LINK REDUNDANCY - Methods and apparatus are provided for timing recovery for an input/output bus with link redundancy. A parallel input/output interface receiver includes a plurality of data receivers, each configured to respectively receive input data from a respective one of n+m channels, where n is an integer greater than one and m is an integer greater than or equal to one. The input data is non-calibration data for the n channels and is calibration data for the m channels. The interface receiver further includes a first phase adjustor configured to provide a first clock signal to the plurality of data receivers for sampling of only the non-calibration data at any given time, and a second phase adjustor configured to provide a second clock signal to the plurality of data receivers for sampling of only the calibration data at any given time. | 12-13-2012 |
20120317062 | RECONFIGURABLE AND CUSTOMIZABLE GENERAL-PURPOSE CIRCUITS FOR NEURAL NETWORKS - A reconfigurable neural network circuit is provided. The reconfigurable neural network circuit comprises an electronic synapse array including multiple synapses interconnecting a plurality of digital electronic neurons. Each neuron comprises an integrator that integrates input spikes and generates a signal when the integrated inputs exceed a threshold. The circuit further comprises a control module for reconfiguring the synapse array. The control module comprises a global final state machine that controls timing for operation of the circuit, and a priority encoder that allows spiking neurons to sequentially access the synapse array. | 12-13-2012 |
20130069831 | PHASED-ARRAY TRANSCEIVER - Systems, methods, devices and apparatuses directed to transceiver devices are disclosed. In accordance with one method, a first set of antenna positions in a first section of a set of sections of a circuit layout for the circuit package is selected. The method further includes selecting another set of antenna positions in another section of the circuit layout such that an arrangement of selected antenna positions of the other set is different from an arrangement of selected antenna positions of a previously selected set of antenna positions. The selecting another set of positions in another section is iterated until selections have been made for a total number of antennas. The selecting the other set is performed such that consecutive unselected positions in the other section do not exceed a predetermined number of positions. In addition, antenna elements are formed at the selected positions to fabricate the circuit package. | 03-21-2013 |
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 |
20130208779 | FEED-FORWARD EQUALIZER ARCHITECTURES - Circuits and methods are provided for efficient feed-forward equalization when sample-and-hold circuitry is employed to generate n time-delayed versions of an input data signal to be equalized. To equalize the input data signal, m data signals are input to m feed-forward equalization (FFE) taps of a current-integrating summer circuit, wherein each of the m data signals corresponds to one of the n time-delayed versions of the input data signal. A capacitance is precharged to a precharge level during a reset period of the current-integrating summer circuit. An output current is generated by each of the m FFE taps during an integration period of the current-integrating summer circuit, wherein the output currents from the m FFE taps collectively charge or discharge the capacitance during the integration period. A gating control signal is applied to an FFE tap during the integration period to disable the FFE tap during a portion of the integration period in which the data signal input to the FFE tap is invalid. | 08-15-2013 |
20130336378 | FEED-FORWARD EQUALIZER ARCHITECTURES - Circuits and methods are provided for efficient feed-forward equalization when sample-and-hold circuitry is employed to generate n time-delayed versions of an input data signal to be equalized. To equalize the input data signal, m data signals are input to m feed-forward equalization (FFE) taps of a current-integrating summer circuit, wherein each of the m data signals corresponds to one of the n time-delayed versions of the input data signal. A capacitance is precharged to a precharge level during a reset period of the current-integrating summer circuit. An output current is generated by each of the m FFE taps during an integration period of the current-integrating summer circuit, wherein the output currents from the m FFE taps collectively charge or discharge the capacitance during the integration period. A gating control signal is applied to an FFE tap during the integration period to disable the FFE tap during a portion of the integration period in which the data signal input to the FFE tap is invalid. | 12-19-2013 |
20140063925 | PARALLEL PROGRAMMING MULTIPLE PHASE CHANGE MEMORY CELLS - Embodiments of the present invention provide a device comprising a plurality of phase change memory cells, a word line, and a plurality of bit lines. Each phase change memory cell is coupled to a corresponding transistor. Each transistor is coupled to the word line. Each bit line is coupled to a phase change memory cell of the device. The device further comprises a programming circuit configured to program at least one phase change memory cell to the SET state by selectively applying a two-stage waveform to the word line and the bit lines of the device. In a first stage, a first predetermined low voltage and a first predetermined high voltage are applied at the word line and the bit lines, respectively. In a second stage, a second predetermined high voltage and a predetermined voltage with decreasing amplitude are applied at the word line and the bit lines, respectively. | 03-06-2014 |
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 |
20140180984 | TIME-DIVISION MULTIPLEXED NEUROSYNAPTIC MODULE WITH IMPLICIT MEMORY ADDRESSING FOR IMPLEMENTING A UNIVERSAL SUBSTRATE OF ADAPTATION - Embodiments of the invention relate to a time-division multiplexed neurosynaptic module with implicit memory addressing for implementing a universal substrate of adaptation. One embodiment comprises a neurosynaptic device including a memory device that maintains neuron attributes for multiple neurons. The module further includes multiple bit maps that maintain incoming firing events for different periods of delay and a multi-way processor. The processor includes a memory array that maintains a plurality of synaptic weights. The processor integrates incoming firing events in a time-division multiplexing manner. Incoming firing events are integrated based on the neuron attributes and the synaptic weights maintained. | 06-26-2014 |
20140180987 | TIME-DIVISION MULTIPLEXED NEUROSYNAPTIC MODULE WITH IMPLICIT MEMORY ADDRESSING FOR IMPLEMENTING A NEURAL NETWORK - Embodiments of the invention relate to a time-division multiplexed neurosynaptic module with implicit memory addressing for implementing a neural network. One embodiment comprises maintaining neuron attributes for multiple neurons and maintaining incoming firing events for different time steps. For each time step, incoming firing events for said time step are integrated in a time-division multiplexing manner. Incoming firing events are integrated based on the neuron attributes maintained. For each time step, the neuron attributes maintained are updated in parallel based on the integrated incoming firing events for said time step. | 06-26-2014 |