Patent application number | Description | Published |
20140285239 | POWER MONITORING CIRCUITRY - Power monitoring circuitry. In some embodiments, comparator circuitry may be configured to receive a first voltage value and a second voltage value, and to identify the greater of the first and second voltage values. Selector circuitry coupled to the comparator circuitry may be configured to power one or more components within the comparator circuitry with a supply voltage corresponding to the greater voltage value. In other embodiments, a method may include identifying, via a comparator, the largest among a plurality of voltage values, and powering one or more logic components within the comparator with the identified voltage value. | 09-25-2014 |
20150084684 | TEMPERATURE DEPENDENT BIASING FOR LEAKAGE POWER REDUCTION - Temperature dependent biasing for leakage power reduction. In some embodiments, a semiconductor device may include a biasing circuit configured to generate a voltage that varies dependent upon a temperature of the semiconductor device and a logic circuit operably coupled to the biasing circuit, where the voltage is applied to a bulk terminal of one or more transistors within the logic circuit, and where the voltage has a value outside of a voltage supply range of the logic circuit. In another embodiment, a semiconductor device may include a biasing circuit configured to generate a voltage that varies according to a temperature of the semiconductor device and a power switch operably coupled to the biasing circuit, where the voltage is applied to a gate terminal of the power switch, and where the voltage has a value outside of a voltage supply range of the power switch. | 03-26-2015 |
20150109054 | READY-FLAG CIRCUITRY FOR DIFFERENTIAL AMPLIFIERS - Ready-flag circuitry for differential amplifiers. In some embodiments, a semiconductor device may include an amplifier including two inputs, and a ready-flag circuit operably coupled to the amplifier, the ready-flag circuit configured to monitor two or more internal nodes of the amplifier and to produce a signal indicating whether a voltage or current difference between the two inputs has been minimized. In other embodiments, a method may include monitoring, via a ready-flag circuit, a first and a second internal node of a differential amplifier, wherein the differential amplifier is part of a bandgap voltage reference circuit and producing, via the ready-flag circuit, a signal indicating whether an output of the bandgap voltage reference circuit has reached a nominal value. | 04-23-2015 |
20150194886 | VOLTAGE REGULATION SYSTEM FOR INTEGRATED CIRCUIT - An integrated circuit (IC) with voltage regulation includes high power and low power domains, low and high voltage regulators and a low power regulator. The low voltage regulator powers the high and low power domains when the IC is in a HIGH power mode. The low power regulator receives a voltage from a high voltage regulator and powers the low power domain when the IC is in a LOW power mode. The IC includes a switching module that disconnects the low voltage regulator from the low power domain when the output voltage of the high voltage regulator is lower than a threshold voltage during power-up and connects the low voltage regulator to the low power domain when the voltage regulated by the high voltage regulator exceeds the threshold voltage. | 07-09-2015 |
20150194887 | POWER GATING TECHNIQUES WITH SMOOTH TRANSITION - In an embodiment, an electronic device includes an integrated circuit (IC) having a plurality of power domains, a first regulator coupled to a given power domain, a second regulator coupled to the given power domain, and a switching circuit coupled between the first and second regulators and configured to control an amount of current drawn by the power domain from the first and/or second regulators. In another embodiment, a method includes controlling an impedance of a switching circuit to change an amount of current, the switching circuit coupled to a given power domain of an IC configured to operate in a first mode followed by a second mode, where the switching circuit is coupled to a first regulator configured to provide more power to the IC than a second regulator, and a transition period includes turning off the first regulator and turning on the second regulator. | 07-09-2015 |
20150211470 | COLD-CRANK EVENT MANAGEMENT - Systems and methods for managing cold-crank events. In an embodiment, a method may include detecting a cold-crank event and setting a switching circuit to a non-conductive state, where the switching circuit is configured to couple a first regulator to a memory circuit such that setting the switching circuit to the non-conductive state de-couples the memory circuit from the first regulator. The method may also include setting the switching circuit to a conductive state in current limitation mode during a recovery period following the cold-crank event to re-couple the memory circuit to the first regulator. In another embodiment, an electronic device include a switching circuit, a first regulator coupled to a first terminal of the switching circuit, a second regulator coupled to a second terminal of the switching circuit, a logic circuit coupled to the switching circuit, and a memory circuit coupled to the second terminal of the switching circuit. | 07-30-2015 |