Abstract: A handheld, therapeutic electrode and connector that are compatible with high voltages from a pulse generator are disclosed. The electrode includes therapeutic terminals on a tip configured to deliver high voltage pulses safely to a patient. The electrode includes sleeves, bosses, wiring channels, and other features that maximize a minimum clearance distance (across non-conductive surfaces) and air clearance between conductive connectors themselves or the connectors and a user, thus preventing dangerous arcing. Internal surfaces and seams are taken into account. The connector and its mating outlet can include similar features to maximize clearance distance. Skirts, skirt holes, and finger stops are also employed, and they can be on either the connector or outlet, or the tip or handle of the electrode.

Abstract: A pulse generation system is disclosed. The pulse generation system includes a controller, an output terminal, and a plurality of pulse generator circuits. The controller is configured to cause a driving signal pulse to be transmitted to any selected one or more of the pulse generator circuits, and to cause the driving signal pulse to not be transmitted to any selected one or more other pulse generator circuits. Each of the pulse generator circuits is configured to generate an output voltage pulse at the output terminal in response to the driving signal pulse being transmitted thereto.

Abstract: Described herein are methods and apparatuses for reducing or eliminating skin glands (e.g., sebaceous, eccrine and apocrine) with an electric treatment. These apparatuses and methods may produce electroporation of cells by applying treatment dose having an energy density sufficient to eliminate or reduce the size of a target gland. Also described herein are methods for treating and/or preventing a disorder of a skin gland. For example, described herein are methods of treating sebaceous hyperplasia.

Abstract: A method of determining a capability of an electrical panel includes providing information relative to the electrical panel to a computer vision software, such as through an image captured by a camera. An attribute of the electrical panel may be analyzed, using the computer vision software, panel at least partially based on the information. An overall electrical power capacity of the electrical panel may be calculated based at least in part on the attribute of the electrical panel. An electrical load on the electrical panel may be calculated based at least in part on the attribute of the electrical panel. A report may be generated that includes an unused electrical power capacity of the electrical panel at least partially based on the electrical load and the overall electrical power capacity of the electrical panel.

Abstract: This disclosure generally relates to systems and methods for facilitating flow within vasculature or other body lumens, channels or passages involving a magnetic field generated by an external magnetic control system and/or facilitating clearance of obstructions (e.g., clots, fluid obstructions) within in-dwelling devices (e.g., shunts, drains, conduits, ports, catheters) involving magnetic particles (e.g., nanoparticles, microparticles) controlled by an external magnetic control system (e.g., one or more rotating permanent magnets or an electromagnetic control system).

Abstract: A method of preconditioning a battery of a vehicle includes determining a baseline preconditioning start time relative to an estimated time of arrival at a charging station. The method further includes analyzing a route of the vehicle to the charging station to determine a route characteristic. The method further includes modifying the baseline preconditioning start time based on the route characteristic to determine a route-based preconditioning start time.

Abstract: Described herein are methods and apparatuses for the application of electric energy treatment(s) to skin tissue to alter pigmentation, and in particular to remove a tattoo. These methods and apparatuses may deliver pulsed electrical energy having a pulse duration in submicrosecond pulse range to provide high-field strength pulses that may effectively release tattoo ink and allow removal of tattoo ink regardless of ink color or composition.

Abstract: Described herein are methods of treating a tissue using a treatment tip apparatus (e.g., devices, systems, etc.) including one, or more preferably a plurality, of electrodes that are protected by an electrode partition, such as an electrode housing (which may be retractable) until pressed against the tissue for deployment of the electrodes and delivery of a therapeutic treatment. In particular, these methods may include the use of a plurality of treatment electrodes (e.g., needle electrodes) and in some examples may include for the delivery of nanosecond pulsed electric fields.

Abstract: A method of determining a capability of an electrical panel includes providing information relative to the electrical panel to a computer vision software, such as through an image captured by a camera. An attribute of the electrical panel may be analyzed, using the computer vision software, panel at least partially based on the information. An overall electrical power capacity of the electrical panel may be calculated based at least in part on the attribute of the electrical panel. An electrical load on the electrical panel may be calculated based at least in part on the attribute of the electrical panel. A report may be generated that includes an unused electrical power capacity of the electrical panel at least partially based on the electrical load and the overall electrical power capacity of the electrical panel.

Abstract: A system for processing compounds having constituent materials of different mechanical characteristics to extract their constituent materials. The system includes a kinetic impactor configured to impact, via a shockwave, compound particles of a preimpact mixture, thereby creating a postimpact mixture including (i) subparticles of 1st-constituent-material and (ii) reduced-compound particles including a 2nd constituent material.

Abstract: An engine in which thrust is achieved by converting electrical energy into high temperature plasma discharges that, in turn, apply thermal, pressure, and/or kinetic energy to a stream of passing air. The engine comprises a plasma region that includes a pair of gapped electrodes, such that the plasma discharges occur in the electrode gap. An energy storage device generates voltage pulses between the electrodes that electrically break down the air as the operating medium within the electrode gap and create plasma discharges.

Abstract: A sub-microsecond pulsed electric field generator is disclosed. The field generator includes a controller, which generates a power supply control signal and generates a pulse generator control signal, and a power supply, which receives the power supply control signal and generates one or more power voltages based on the received power supply control signal. The field generator also includes a pulse generator which receives the power voltages and the pulse generator control signal, and generates one or more pulses based on the power voltages and based on the pulse generator control signal. In some embodiments, the controller receives feedback signals representing a value of a characteristic of or a result of the pulses and generates at least one of the power supply control signal and the pulse generator control signal based on the received feedback signals.

Abstract: A pulse generator discharge circuit is disclosed. The circuit includes one or more discharge stages, each discharge stage including a plurality of control input terminals. The circuit also includes first and second discharge terminals, and a plurality of serially connected switches electrically connected between the first and second discharge terminals, where a conductive state of each of the switches is controlled by a control signal. The circuit also includes a plurality of inductive elements configured to generate the control signals for the serially connected switches, where each inductive element is configured to generate a control signal for one of the serially connected switches in response to one or more input signals at one or more of the control input terminals, and where each of the serially connected switches is configured to receive a control signal from a respective one of the inductive elements.

Abstract: A constant force generator includes a case of a tube-shaped ferromagnetic material and extending in an axial direction, a tube-shaped stator disposed in the case, and a rod-shaped shaft disposed in the tube-shaped stator via a gap. The tube-shaped stator includes N main permanent magnets magnetized in a radial direction and disposed adjacently at regular angular intervals of (360/N) degrees, and an even number of secondary permanent magnets magnetized in a circumferential direction and sandwiching each of the N main permanent magnets on both sides in the circumferential direction. The secondary permanent magnets sandwich the both sides of each main permanent magnet so that magnetic poles of the secondary permanent magnets, facing the both sides of the sandwiched main permanent magnet, have a polarity the same as an inside magnetic pole of the sandwiched main permanent magnet. The rod-shaped shaft at least includes a shaft portion of a magnetic material.

Abstract: This invention provides secure, policy-based separation of data and applications on computer, especially personal computers that operate in different environments, such as those including personal applications and corporate applications, so that both types of applications can run simultaneously while complying with all required policies. The invention enables employees to use their personal devices for work purposes, or work devices for personal purposes. The secure, policy-based separation is created by dividing the data processing device into two or more “domains,” each with its own policies. These policies may be configured by the device owner, an IT department, or other data or application owner.

Abstract: Systems and methods are provided for aggregating and assigning power capacity for charging electric vehicles and providing power to other loads. The systems include a DC bus system used to harmonize and combine power drawn from grid connections having different electrical characteristics such as different voltages or phase levels and from other devices such as energy storage systems and generators at the site. Using the systems and methods can help enable utility customer sites to providing electric vehicle charging, especially for multiple electric vehicles, where the sites would otherwise not have sufficient power to do so without significant and expensive service upgrades and modifications.

Abstract: Applicators, systems, and methods for delivering electrical energy to a target treatment region with large area surface electrodes are disclosed. In one example, a system may include a housing, a pulse generator, and a treatment applicator coupled to the pulse generator and configured to deliver sub-microsecond high-voltage electric pulses from the pulse generator. The treatment applicator may include a first and second electrodes coupled to a substrate, where the first and second electrodes are configured to provide a uniform gap between edges of the first and second electrodes.

Abstract: A multi-axis linear motor actuator has a circuit board having a size covering coil portions in linear shaft motors arranged in a row, and combined with the linear shaft motors to be adjacent thereto and parallel to its arrangement direction; and magnetic shielding plates, longer than the coil portions, arranged and fixed along an axial direction at positions corresponding to positions between adjacent coil portions. Hall sensors are installed in the circuit board in each region corresponding to each linear shaft motor at intervals in a moving direction of a shaft of each linear shaft motor. Each magnetic shielding plate has a wide portion with a width greater than a diameter of the coil portion at a part corresponding to the region where the Hall sensors are installed. The circuit board has first slits for inserting the wide portions. The Hall sensors are installed adjacent to the wide portion.