Abstract: Apparatuses, capacitor arrays, and methods for generating therapeutic compressed acoustic waves (e.g., shock waves). In the apparatuses and at least some of the methods, a plurality of electrodes can disposed in a chamber that is defined by a housing and configured to be filled with liquid, and a plurality of capacitors can be electrically connected to the electrodes and can be carried by (e.g., physically coupled to) the housing. Voltage pulses can be applied simultaneously to the plurality of electrodes (e.g., to begin to vaporize and ionize portions of the liquid to provide at least one inter-electrode conductive path between the plurality of electrodes) and to the capacitors to charge the plurality of capacitors). The plurality of capacitors can be configured to, upon reaching a threshold charge, discharge to the plurality of electrodes (e.g.

Abstract: An apparatus comprising: a model to generate adjusted tuning parameters of a thread scheduling policy based on a tradeoff indication value of a target system; and a workload monitor to: execute a workload based on the thread scheduling policy; obtain a performance score and a power score from the target system based on execution of the workload, the performance score and the power score corresponding to a tradeoff indication value; compare the tradeoff indication value to a criterion; and based on the comparison, initiate the model to re-adjust the adjusted tuning parameters.

Abstract: Disclosed herein is a resuscitation device, comprising an electric pulse generator configured to generate an electric pulse that is administered to a subject, electrodes operative to administer the electric pulse to the subject, at least one sensor configured to measure vital signs of the subject, at least one processing unit configured to monitor the vital signs measured by the at least one sensor, determine the housing and electrodes are properly placed on the subject according to the monitoring of the vital signs, determine what treatment has to be administered to the subject, generate notification instructing the treatment to be administered to the subject, and providing real-time, continuous feedback of treatment provided and condition of the subject.

Abstract: Disclosed herein is a resuscitation device facilitating the administration of cardiopulmonary resuscitation to a subject, the resuscitation device comprising a housing having a top surface and a bottom surface, said top surface having a concave dell configured to guide on the top surface a hand positioning of a rescuer administrating a cardiopulmonary resuscitation to a subject, and said bottom surface configured to position and stabilize the housing over a sternum of the subject, and wherein the housing is configured to transmit a uniform distribution of the cardiopulmonary resuscitation force to the chest of the subject, said uniform distribution facilitates distributing the cardiopulmonary resuscitation force over a surface area that greater than the area of the top surface that directly receives the cardiopulmonary resuscitation force, thereby facilitating injury and contusion prevention to ribs and the sternum of the subject.

Abstract: Apparatuses, capacitor arrays, and methods for generating therapeutic compressed acoustic waves (e.g., shock waves). In the apparatuses and at least some of the methods, a plurality of electrodes can disposed in a chamber that is defined by a housing and configured to be filled with liquid, and a plurality of capacitors can be electrically connected to the electrodes and can be carried by (e.g., physically coupled to) the housing. Voltage pulses can be applied simultaneously to the plurality of electrodes (e.g., to begin to vaporize and ionize portions of the liquid to provide at least one inter-electrode conductive path between the plurality of electrodes) and to the capacitors to charge the plurality of capacitors). The plurality of capacitors can be configured to, upon reaching a threshold charge, discharge to the plurality of electrodes (e.g.

Abstract: An apparatus comprising: a model to generate adjusted tuning parameters of a thread scheduling policy based on a tradeoff indication value of a target system; and a workload monitor to: execute a workload based on the thread scheduling policy; obtain a performance score and a power score from the target system based on execution of the workload, the performance score and the power score corresponding to a tradeoff indication value; compare the tradeoff indication value to a criterion; and based on the comparison, initiate the model to re-adjust the adjusted tuning parameters.

Abstract: Systems and methods utilizing RF energy to treat a patient's skin (e.g., dermis and hypodermis) or other target tissue including at a depth below a tissue surface (e.g., skin surface, mucosal surfaces of the vagina or esophagus) are provided herein. In various aspects, the methods and systems described herein can provide a RF-based treatment in which the deposition of RF energy can be selectively controlled to help ensure heating uniformity during one or more of body sculpting treatment (lipolysis), skin tightening treatment (laxity improvement), cellulite treatment, vaginal laxity or rejuvenation treatment, urinary incontinence treatment, fecal incontinence treatment, all by way of non-limiting examples. In various aspects, the systems can comprise one or more sources of RF energy (e.g., a RF generator), a treatment applicator comprising one or more electrode arrays configured to be disposed in contact with a tissue surface, and a return electrode (e.g., a neutral pad) to the tissue surface.

Abstract: Methods and apparatus relating to techniques for dynamically selecting optimum graphics logic frequency and/or graphics logic power gating configuration are described. In an embodiment, multi-rate control logic determines processor active slice count and processor frequency based at least in part on a target Frames Per Second (FPS) value and a current FPS value. The multi-rate control logic includes slow rate control logic to determine slice gating and operating frequency and a fast rate control logic to determine operating frequency of the processor. Other embodiments are also disclosed and claimed.

Abstract: Systems and methods utilizing RF energy to treat a patient's skin (e.g., dermis and hypodermis) or other target tissue including at a depth below a tissue surface (e.g., skin surface, mucosal surfaces of the vagina or esophagus) are provided herein. In various aspects, the methods and systems described herein can provide a RF-based treatment in which the deposition of RF energy can be selectively controlled to help ensure heating uniformity during one or more of body sculpting treatment (lipolysis), skin tightening treatment (laxity improvement), cellulite treatment, vaginal laxity or rejuvenation treatment, urinary incontinence treatment, fecal incontinence treatment, all by way of non-limiting examples. In various aspects, the systems can comprise one or more sources of RF energy (e.g., a RF generator), a treatment applicator comprising one or more electrode arrays configured to be disposed in contact with a tissue surface, and a return electrode (e.g., a neutral pad) to the tissue surface.

Abstract: A non-contiguous group of cells in a battery of cells is selected for charging or discharging the battery.

Abstract: An embodiment includes a C-element logic gate implemented as a spin logic device that provides a compact and low-power implementation of asynchronous logic by implementing a C-element with spintronic technology. An embodiment includes a first nanopillar including a first contact and a first fixed magnetic layer; a second nanopillar including a second contact and a second fixed magnetic layer; and a third nanopillar including a third contact, a tunnel barrier, and a third fixed magnetic layer; wherein (a) the first, second, and third nanopillars are all formed over a free magnetic layer, and (b) the third fixed magnetic layer, the tunnel barrier, and the free magnetic layer form a magnetic tunnel junction (MTJ). Other embodiments are described herein.

Abstract: The disclosed invention reduces current in the ignition circuit during normal operation (after ignition) by redirecting portion of the plasma current via a bypass switch.

Abstract: An embodiment includes a C-element logic gate implemented as a spin logic device that provides a compact and low-power implementation of asynchronous logic by implementing a C-element with spintronic technology. An embodiment includes a first nanopillar including a first contact and a first fixed magnetic layer; a second nanopillar including a second contact and a second fixed magnetic layer; and a third nanopillar including a third contact, a tunnel barrier, and a third fixed magnetic layer; wherein (a) the first, second, and third nanopillars are all formed over a free magnetic layer, and (b) the third fixed magnetic layer, the tunnel barrier, and the free magnetic layer form a magnetic tunnel junction (MTJ). Other embodiments are described herein.

Abstract: A non-contiguous group of cells in a battery of cells is selected for charging or discharging the battery.

Abstract: A non-contiguous group of cells in a battery of cells is selected for charging or discharging the battery.

Abstract: A plasma flood gun for an ion implantation system includes an insulating block portion and first and second conductive block portions disposed on opposite sides of the insulating block portion. Conductive straps can be coupled between the first and second conductive block portions. The conductive block portions and the central body portion include recesses which form a closed loop plasma chamber. A power source is coupled to the conductive block portions for inductively coupling radio frequency electrical power into the closed loop plasma chamber to excite the gaseous substance to generate a plasma. The respective recess in the second conductive block portion includes a pinch region having a cross-sectional dimension that is smaller than a cross-sectional area of portion of the closed loop plasma chamber directly adjacent the pinch region. The pinch region can be positioned immediately adjacent an outlet portion formed in the second conductive block portion.

Abstract: A plasma flood gun for an ion implantation system includes an insulating block portion and first and second conductive block portions disposed on opposite sides of the insulating block portion. Conductive straps can be coupled between the first and second conductive block portions. The conductive block portions and the central body portion include recesses which form a closed loop plasma chamber. A power source is coupled to the conductive block portions for inductively coupling radio frequency electrical power into the closed loop plasma chamber to excite the gaseous substance to generate a plasma. The respective recess in the second conductive block portion includes a pinch region having a cross-sectional dimension that is smaller than a cross-sectional area of portion of the closed loop plasma chamber directly adjacent the pinch region. The pinch region can be positioned immediately adjacent an outlet portion formed in the second conductive block portion.

Abstract: A system and method are provided for delivering power to a dynamic load. The system includes a power supply providing DC power having a substantially constant power open loop response, a power amplifier for converting the DC power to RF power, a sensor for measuring voltage, current and phase angle between voltage and current vectors associated with the RF power, an electrically controllable impedance matching system to modify the impedance of the power amplifier to at least a substantially matched impedance of a dynamic load, and a controller for controlling the electrically controllable impedance matching system. The system further includes a sensor calibration measuring module for determining power delivered by the power amplifier, an electronic matching system calibration module for determining power delivered to a dynamic load, and a power dissipation module for calculating power dissipated in the electrically controllable impedance matching system.

Abstract: Determining linear modulator dynamics in an interferometric fiber-optic gyroscope may be accomplished by applying a stimulus at a point within the gyroscope, observing a response in an output of the gyroscope, and determining, from the observed response, the linear modulator dynamics.

Abstract: Determining linear modulator dynamics in an interferometric fiber-optic gyroscope may be accomplished by applying a stimulus at a point within the gyroscope, observing a response in an output of the gyroscope, and determining, from the observed response, the linear modulator dynamics.