Patent application number | Description | Published |
20100020910 | PHASE-LOCKED LOOP SYSTEM WITH A PHASE-ERROR SPREADING CIRCUIT - A phase-locked loop (PLL) system including a phase-frequency detector for generating an up signal or a down signal based on a phase difference between a reference clock and a feedback clock is provided. The PLL system further includes a phase-error spreading circuit for generating phase-spread pulses based on a relationship between a first time attribute of the up signal or the down signal and a second time attribute of the phase-spread pulses. The PLL system further includes a voltage-controlled oscillator (VCO) for generating a VCO clock based on the phase-spread pulses. The PLL system may also include a charge pump that generates a pumping signal based on the phase-spread pulses. | 01-28-2010 |
20100188131 | LEVEL SHIFTER FOR CHANGE OF BOTH HIGH AND LOW VOLTAGE - A circuit comprises first and second inverters, first, second, third, and fourth transistors, and an enabling circuit. The first and second inverters each have an input terminal for receiving one of the first or second input signals, an output terminal, and first and second supply terminals. The first transistor is coupled to a first power supply terminal, to the output terminal of the second inverter, and to the first inverter. The second transistor is coupled to the first power supply terminal, to the output terminal of the first inverter, and to the first supply terminal of the second inverter. The third and fourth transistor are coupled to the second supply terminals of the first and second inverters, respectively, and each includes a control electrode and a second current electrode. The enabling circuit is for controlling the third and fourth transistors to reduce a leakage current in the circuit. | 07-29-2010 |
20100308793 | PHASE LOCKED LOOP DEVICE AND METHOD THEREOF - A phase locked loop device includes a phase detector that measures a difference in phase between a reference clock signal and an output clock signal of the phase locked loop. The phase detector provides a pulse having a width indicative of the phase difference. A phase measurement module determines a digital value based on the pulse width. Accordingly, the digital value provides an indication of the phase difference between the reference clock signal and the output clock signal. A series of the digital values can be recorded to indicate how the phase difference varies over time, thereby providing a useful characterization of device behavior. | 12-09-2010 |
20100308912 | AMPLIFYING CIRCUIT WITH OFFSET COMPENSATION - An amplifying circuit has an offset calibration mode and a normal mode. The amplifying circuit includes an amplifier having a non-inverting input and an inverting input for receiving, during the normal mode, a first input signal and a second input signal and an output for providing a high speed output signal, wherein the first input signal is a reference voltage or a high speed signal and the second input signal is a high speed signal. The amplifying circuit further includes a first transmission gate and a second transmission gate coupled in series between the non-inverting input and an inverting input that are enabled during the offset calibration mode. A benefit of this approach is that capacitance between the inverting and non-inverting inputs is reduced by the first and second transmission gates being in series. There is further benefit in reducing this capacitance by having each transmission gate receive an enable signal from a different source. | 12-09-2010 |
20100310030 | PHASE LOCKED LOOP DEVICE AND METHOD THEREOF - A phase locked loop device includes a phase detector that measures a difference in phase between a reference clock signal and an output clock signal provided to a device module. The phase detector provides a pulse having a width indicative of the phase difference. If the phase difference exceeds one of a plurality of threshold values, in indicator can be asserted. Based on the indicator, a control module can take remedial action, such as providing a different clock signal to the device module or triggering an interrupt at a processor device. | 12-09-2010 |
20100315119 | MEMORY CONTROLLER CALIBRATION - Components of a memory controller are calibrated in a select sequence to compensate for variances in skew and signal level variations. The offset bias of the receiver of the I/O cell and the termination resistance of the I/O cell are calibrated. The duty cycles of the transmit path and receive path associated with the I/O cell can be calibrated using the calibrated receiver. In one aspect, the driver of the I/O cell can be calibrated prior to calibrating the receiver. Performing the calibration processes of the memory controller in one of the particular sequences described herein improves the timing budgets for the signaling conducted by the memory controller. | 12-16-2010 |
20100315141 | MULTIPLE-STAGE, SIGNAL EDGE ALIGNMENT APPARATUS AND METHODS - Signal edge alignment embodiments include multiple delay stages connected in series. Each delay stage includes a delay line, an interface circuit, and a tap selection circuit. The delay line applies fixed-width delays to an input signal to produce delayed versions of the input signal at a plurality of taps. The interface circuit, which is characterized by an inherent interface circuit delay, passes one of the delayed versions to an interface circuit output in response to a control signal. The tap selection circuit determines a finally-identified tap of the plurality of taps by determining an initially-identified tap at which a delayed version of the input signal most closely has a desired alignment with the input signal, and by identifying the finally-identified tap in the control signal as a tap that occurs earlier in the delay line than the initially-identified tap. This compensates for the inherent delay of the delay stage. | 12-16-2010 |
20100315171 | VOLTAGE TRANSLATION USING FEEDBACK TO ADJUST OUTPUT VOLTAGE RANGE - Apparatus are provided for a voltage-controlled oscillator module. A voltage-controlled oscillator module comprises an input node for receiving an input voltage, a voltage-controlled oscillator, and voltage translation circuitry coupled between the input node and the voltage-controlled oscillator. The voltage translation circuitry is configured to generate a control voltage based on the input voltage and the voltage-controlled oscillator generates an oscillating signal at an oscillation frequency in response to the control voltage. Biasing circuitry is coupled to the voltage translation circuitry, and the biasing circuitry is configured to adjust the ratio of the control voltage to the input voltage. | 12-16-2010 |
20100316167 | COMMON MODE TRACKING RECEIVER - A clock receiver ( | 12-16-2010 |
20110181326 | PHASE-LOCKED LOOP HAVING A FEEDBACK CLOCK DETECTOR CIRCUIT AND METHOD THEREFOR - A method for a phase-locked loop (PLL) in an integrated circuit, wherein the PLL comprises a voltage-controlled oscillator (VCO). The method includes, in a training mode: (1) setting a control voltage of the VCO at a first voltage level; (2) increasing the control voltage of the VCO from the first voltage level to a second voltage level, until a loss of the feedback signal is detected; and (3) storing an indicator value corresponding to the second voltage level of the control voltage of the VCO. The method further includes, in a normal mode: (1) monitoring a voltage level of the control voltage of the VCO by generating a monitored indicator value corresponding to the voltage level of the control voltage of the VCO; and (2) asserting the loss of feedback signal based on a comparison of the monitored indicator value and the indicator value. | 07-28-2011 |
20130257513 | FULLY COMPLEMENTARY SELF-BIASED DIFFERENTIAL RECEIVER WITH STARTUP CIRCUIT - In accordance with at least one embodiment, an improved voltage headroom self-biased receiver is provided. In accordance with at least one embodiment, tail current sources are biased so as to be cross-coupled with respect to each other. In accordance with at least one embodiment, startup control is provided to counter defect-induced current and to ensure the circuit can function properly even with large amounts of defect current. In accordance with at least one embodiment, a positive type (p type) channel metal oxide semiconductor (PMOS) tail current transistor is modulated by a negative type (n type) channel metal oxide semiconductor (NMOS) differential pair virtual negative supply voltage and a NMOS tail current transistor is modulated by a PMOS differential pair virtual positive supply voltage. The amplifier's output common mode is thus self correcting to p type to n type transistor strength differences. | 10-03-2013 |
20130314138 | STATE RETENTION SUPPLY VOLTAGE DISTRIBUTION USING CLOCK NETWORK SHIELDING - An integrated circuit including a state retention node, a conductive clock network shielding and multiple state retention devices for maintaining a state of the integrated circuit during the low power state. The state retention node receives a state retention supply voltage which remains at an operative voltage level during a low power state. The conductive clock network shielding is distributed with clock signal conductors and is coupled to the state retention node. Each state retention device has a supply voltage input coupled to the clock network shielding so that it remains powered during the low power state. The state retention node may be implemented as a minimal set of conductive traces. A state retention buffer may be provided for buffering a power gating signal indicative of the low power state, in which the buffer has a supply voltage input coupled to the clock network shielding. | 11-28-2013 |
20140084974 | PHASE LOCKED LOOP WITH BURN-IN MODE - A phase locked loop having a normal mode and a burn-in mode. The logic portion is coupled to a logic power supply terminal and includes a clock receiver coupled to a phase frequency detector. The analog portion has a charge pump coupled to the phase frequency detector and to an analog power supply terminal. The analog portion also has a voltage controlled oscillator coupled to the charge pump at an analog node and to the analog power supply terminal. The phase locked loop has a node control circuit that is coupled to the analog node during the burn-in mode that controls a voltage at the analog node sufficiently below a voltage at the analog power supply terminal to avoid over-stressing the charge pump and the voltage controlled oscillator during the burn-in mode. | 03-27-2014 |
20140084975 | VOLTAGE TRANSLATION CIRCUIT - A voltage translation circuit ( | 03-27-2014 |
20140086277 | THERMAL SENSOR SYSTEM AND METHOD BASED ON CURRENT RATIO - A thermal sensor system which includes a thermal sensor and a voltage control network which applies a reference voltage level and a delta voltage level to the same or different thermal sensors. The thermal sensor develops a reference current signal in response to the reference voltage level and a delta current signal in response to the delta voltage level. A current gain network adjusts gain of the delta current signal. A current compare sensor, which is responsive to the reference current signal and the delta current signal, provides a comparison metric. A controller controls the current gain network to adjust gain of the delta current signal while monitoring the comparison metric to determine a gain differential value indicative of a current ratio between the current signals. The controller determines a temperature value based on the gain differential value. A LUT may be used to retrieve the temperature. | 03-27-2014 |
20140086279 | THERMAL SENSOR SYSTEM AND METHOD BASED ON CURRENT RATIO - A thermal sensor system including at least one thermal sensor, a voltage control network, a current gain network, a current compare sensor, and a controller. The voltage control network applies reference and delta voltage levels to a thermal sensor, which develops reference and delta current signals. The current gain network is used to adjust current gain. The current compare sensor is responsive to the reference and delta current signals and provides a comparison metric. The controller selects a temperature subrange and controls the current gain network to adjust the gain of the delta current signal to determine a gain differential value indicative of the temperature. The controller may select from among different sized thermal sensors, current mode gain values, and control voltages corresponding with each of multiple temperature subranges. Any one or more of these parameters may be adjusted to adjust an operating point for selecting a corresponding temperature subrange. | 03-27-2014 |
20140117953 | METHOD AND APPARATUS FOR A TUNABLE DRIVER CIRCUIT - A driver circuit having an adjustable output signal includes a logic circuit configured to receive an input signal into a first input terminal and an output circuit coupled to the logic circuit, wherein the output circuit is configured to generate, at an output terminal of the output circuit, an output signal having a signal level that changes in response to a signal level of the input signal. The driver circuit further includes a feedback circuit coupled to a second input terminal of the logic circuit. The feedback circuit includes first and second gate terminals coupled to the output terminal and a third gate terminal coupled to a control signal supply, wherein the feedback circuit is configured to control a maximum level of the output signal from the driver circuit based on an operating threshold of the feedback circuit as set by a control signal generated by the control signal supply. | 05-01-2014 |
20140153148 | OVER VOLTAGE PROTECTION FOR A THIN OXIDE LOAD CIRCUIT - An IC includes: a substrate having a thick oxide portion and a thin oxide portion; a load circuit disposed on the thin oxide portion and coupled between a supply node and a virtual supply node; and a current source circuit and protection circuit disposed on the substrate. The current source circuit has an output coupled to the virtual supply node and is operable to provide a voltage at the virtual supply node. The protection circuit includes a sensing portion and a protection portion. The sensing portion is coupled to the virtual supply node and is operable to detect the voltage at the virtual supply node. The protection portion is coupled to the sensing portion and is operable, in response to the sensed voltage, to prevent a difference in voltage between the voltage at the virtual supply node and a second voltage at the supply node from exceeding a maximum voltage. | 06-05-2014 |