Abstract: An integrated circuit (IC) is provided for in-situ anomaly detection. Sensors in the IC generates sensor datasets including information indicating conditions in the IC. A processing unit in the IC uses a sensor dataset and a model to detect and classify the anomaly. The processing unit may filter the sensor dataset, extract features from the filtered sensor dataset, and input the features into the model. The model outputs one or more classifications of the anomaly. A feature may be a distance vector that represents a difference between a data value in the filtered sensor dataset from a reference data value. The model may be a network of bit-cells in the IC. The model may be continuously trained in-situ, i.e., on the IC. The processing unit may provide the classifications to another processing unit in the IC. The other processing unit may mitigate the anomaly based on the classifications.

Abstract: Methods and systems to provide a multi-Vcc environment, such as to selectively boost an operating voltage of a logic block and/or provide a level-shifted control to the logic block. A multi-Vcc environment may be implemented to isolate a Vmin-limiting logic block from a single-Vcc environment, such as to reduce Vmin and/or improve energy efficiency in the single-Vcc environment. The logic block may include bit cells of a register file, a low-level processor cache, and/or other memory system. A cell Vcc may be boosted during a read mode and/or write wordlines (WWLs) and/or read wordlines (RWLs) may be asserted with boost. A wordline decoder may include a voltage level shifter with differential split-level logic, and a dynamic NAND, which may include NAND logic, a keeper circuit, and logic to delay a keeper control based on a delay of the level shifter to reduce contention during an initial NAND evaluation phase.

Abstract: In one embodiment, an energy harvesting system includes multiple-input-multiple-output switched-capacitor (MIMOSC) circuitry comprising a plurality of switched-capacitor circuit units to receive a plurality of direct current (DC) input voltages at respective input terminals of the switched-capacitor circuit unit, combine the received DC input voltages, and provide the combined DC input voltages at an output terminal of the switched-capacitor circuit unit. The energy harvesting system also includes maximum power point tracking (MPPT) circuitry coupled to switches of the switched-capacitor circuit units of the MIMOSC circuitry. The MPPT circuitry is to provide a plurality of switching signals to the switches of the switched-capacitor circuit units. The MIMOSC circuitry is to provide a plurality of DC output voltages to respective loads based on the switching signals from the MPPT circuitry.

Abstract: Methods and systems to provide a multi-Vcc environment, such as to selectively boost an operating voltage of a logic block and/or provide a level-shifted control to the logic block. A multi-Vcc environment may be implemented to isolate a Vmin-limiting logic block from a single-Vcc environment, such as to reduce Vmin and/or improve energy efficiency in the single-Vcc environment. The logic block may include bit cells of a register file, a low-level processor cache, and/or other memory system. A cell Vcc may be boosted during a read mode and/or write wordlines (WWLs) and/or read wordlines (RWLs) may be asserted with boost. A wordline decoder may include a voltage level shifter with differential split-level logic, and a dynamic NAND, which may include NAND logic, a keeper circuit, and logic to delay a keeper control based on a delay of the level shifter to reduce contention during an initial NAND evaluation phase.

Abstract: Described is an apparatus which comprises: a memory bit-cell; a local bit-line (LBL) coupled to the memory bit-cell via a read port device; a NAND gate circuitry coupled to the LBL; and a stack of keepers coupled to the LBL, wherein at least one transistor of the stack of keepers is controllable according to an output of the NAND gate circuitry, wherein the stack of keepers includes transistors with variable strength which are to be turned on overtime.

Abstract: Various embodiments of the invention may analyze previous patterns of harvested energy to predict future patterns of available harvested energy. This prediction may then be used to choose from among multiple methods of energy reduction techniques. The energy reduction techniques may include multiple versions of reducing or modifying instruction execution. Reduced instruction execution may include reducing the precision of various calculations.

Abstract: Methods and systems to provide a multi-Vcc environment, such as to selectively boost an operating voltage of a logic block and/or provide a level-shifted control to the logic block. A multi-Vcc environment may be implemented to isolate a Vmin-limiting logic block from a single-Vcc environment, such as to reduce Vmin and/or improve energy efficiency in the single-Vcc environment. The logic block may include bit cells of a register file, a low-level processor cache, and/or other memory system. A cell Vcc may be boosted during a read mode and/or write wordlines (WWLs) and/or read wordlines (RWLs) may be asserted with boost. A wordline decoder may include a voltage level shifter with differential split-level logic, and a dynamic NAND, which may include NAND logic, a keeper circuit, and logic to delay a keeper control based on a delay of the level shifter to reduce contention during an initial NAND evaluation phase.

Abstract: In one embodiment, an energy harvesting system includes multiple-input-multiple-output switched-capacitor (MIMOSC) circuitry comprising a plurality of switched-capacitor circuit units to receive a plurality of direct current (DC) input voltages at respective input terminals of the switched-capacitor circuit unit, combine the received DC input voltages, and provide the combined DC input voltages at an output terminal of the switched-capacitor circuit unit. The energy harvesting system also includes maximum power point tracking (MPPT) circuitry coupled to switches of the switched-capacitor circuit units of the MIMOSC circuitry. The MPPT circuitry is to provide a plurality of switching signals to the switches of the switched-capacitor circuit units. The MIMOSC circuitry is to provide a plurality of DC output voltages to respective loads based on the switching signals from the MPPT circuitry.

Abstract: Described is an apparatus which comprises: a memory bit-cell; a local bit-line (LBL) coupled to the memory bit-cell via a read port device; a NAND gate circuitry coupled to the LBL; and a stack of keepers coupled to the LBL, wherein at least one transistor of the stack of keepers is controllable according to an output of the NAND gate circuitry, wherein the stack of keepers includes transistors with variable strength which are to be turned on overtime.

Abstract: Some embodiments include apparatuses and methods having a power switching unit to receive a first voltage and provide a second voltage having a value based on a value of the first voltage, a first loop to provide digital control information to control a switching of the power switching unit in order to maintain a relationship between the value of the second voltage and a value of a reference voltage, and a second loop coupled to the power switching unit and the first loop to calculate a value of energy consumption of at least a portion of the apparatus based at least on the digital control information.

Abstract: Generally, this disclosure describes an apparatus. The apparatus includes switch controller circuitry. The switch controller circuitry includes dead time logic circuitry to determine an estimated dead time interval between a turn off of a first switch and a turn on of a second switch. The first switch and the second switch are coupled at a switched node. The estimated dead time interval is determined based, at least in part, on a difference between an input voltage, Vin, and a switched voltage, Vsw, detected at the switched node just prior to turning off the first switch, a parasitic capacitance, Cpar, associated with the switched node and a maximum inductor current, IL,max. The difference between Vin and Vsw represents the maximum inductor current.

Abstract: Sequential circuits with error-detection are provided. They may, for example, be used to replace traditional master-slave flip-flops, e.g., in critical path circuits to detect and initiate correction of late transitions at the input of the sequential. In some embodiments, such sequentials may comprise a transition detector with a time borrowing latch.

Abstract: Described is an apparatus for power management. The apparatus comprises: a first power supply node; a second power supply node; a controllable device coupled to the first power supply node and to the second power supply node, the controllable device operable to short the first power supply node to the second power supply node; a load coupled to the second power supply node; and a charge recovery pump (CRP) coupled to the first and second power supply nodes.

Abstract: Described is an apparatus which comprises: a first oscillator to generate a first clock signal a second oscillator to generate a second clock signal; a phase frequency detector to detect phase difference between the first and second clock signals, and to generate a phase difference; and an output stage, coupled to a load, to generate a power supply for the load according to the phase difference.

Abstract: Generally, this disclosure describes an apparatus. The apparatus includes switch controller circuitry and zero crossing logic circuitry. The switch controller circuitry is to control a conduction state of a high side switch and a low side switch in a DC to DC converter. The zero crossing logic circuitry includes phase comparator circuitry, a first clocking circuitry and a second clocking circuitry. Each clocking circuitry includes one or more delay elements. The zero crossing logic circuitry is to monitor a switch node voltage, Vsw, and to determine whether Vsw is greater than a reference, Vref. The switch controller circuitry is to turn off a low side switch if Vsw is greater than Vref while the low side switch is turned on, Vsw greater than Vref corresponding to a negative inductor current.

Abstract: A router of a network-on-chip receives delay information associated with a plurality of links of the network-on-chip. The router determines at least one link of a data path based on the delay information.

Abstract: The disclosed system and method detect and correct register file read path errors that may occur as a result of reducing or eliminating supply voltage guardbands and/or frequency guardbands for a CPU, thereby increasing overall energy efficiency of the system.

Abstract: Methods and systems to provide a multi-Vcc environment, such as to selectively boost an operating voltage of a logic block and/or provide a level-shifted control to the logic block. A multi-Vcc environment may be implemented to isolate a Vmin-limiting logic block from a single-Vcc environment, such as to reduce Vmin and/or improve energy efficiency in the single-Vcc environment. The logic block may include bit cells of a register file, a low-level processor cache, and/or other memory system. A cell Vcc may be boosted during a read mode and/or write wordlines (WWLs) and/or read wordlines (RWLs) may be asserted with boost. A wordline decoder may include a voltage level shifter with differential split-level logic, and a dynamic NAND, which may include NAND logic, a keeper circuit, and logic to delay a keeper control based on a delay of the level shifter to reduce contention during an initial NAND evaluation phase.

Abstract: Described is an apparatus which comprises: a clamp coupled between a first power supply and a second power supply, the clamp including a plurality of transistors, a circuit to operate with the second power supply; and a control unit to turn on and off the plurality of transistors to adjust the second power supply when the apparatus enters a low power mode. The control unit includes a first comparator to compare the second power supply with a first reference, a second comparator to compare the second power supply with a second reference, and a counter. The counter counts up when the second power supply is higher than the first reference and counts down when the second power supply is lower than the second reference.

Abstract: Generally, this disclosure describes an apparatus. The apparatus includes switch controller circuitry. The switch controller circuitry includes dead time logic circuitry to determine an estimated dead time interval between a turn off of a first switch and a turn on of a second switch. The first switch and the second switch are coupled at a switched node. The estimated dead time interval is determined based, at least in part, on a difference between an input voltage, Vin, and a switched voltage, Vsw, detected at the switched node just prior to turning off the first switch, a parasitic capacitance, Cpar, associated with the switched node and a maximum inductor current, IL,max. The difference between Vin and Vsw represents the maximum inductor current.