Abstract: An example augmented-reality headset comprises a frame portion, a temple arm portion coupled with the frame portion, and a metal-encased battery cell having an exterior surface that defines a non-rectangular shape. The metal-encased battery cell is configured to be housed within the temple arm portion, and the non-rectangular shape of the exterior surface follows an interior shape of an internal surface of the temple arm portion. The augmented-reality headset also comprises one or more artificial-reality processing or presentation devices, wherein at least one of the one or more artificial-reality processing or presentation devices is configured to receive power from the metal-encased battery cell.

Abstract: According to examples, systems and methods for implementing a conductive trace via laser direct structuring (LDS) and a light-emitting diode (LED) via surface-mount technology (SMT) on a carrier structure of a display device are described. A method may include printing a conductive trace onto a carrier, mounted a light-emitting diode (LED) onto the carrier, and attaching a flexible printed circuit (FPC) to the carrier, wherein the light-emitting diode (LED) is communicatively coupled to the flexible printed circuit (FPC) via the conductive trace.

Abstract: A swappable battery and a swappable battery system for a near-eye device are described. In one aspect, the swappable battery may be detachably integrated into an outer surface of a near-eye device such that the swappable battery may be easily removable and replaceable by the user. In another aspect, the lid of the swappable battery may form an outer surface of the near-eye device when the swappable battery is attached. In some examples, the swappable battery may be detachably attached within a temple arm of a pair of smartglasses such that the outer surface of the swappable battery and the outer surface of the temple arm are substantially contiguous and flush.

Abstract: Can battery cells are described. The can battery cell includes a battery cell core that is housed in a rigid enclosure. The enclosure can be made of metal or other rigid material. A front face of the enclosure includes an anode tab and a cathode tab extending from the front face. A circuit module is electrically coupled to the anode tab and the cathode tab, and overlies at least a portion of the front face of the enclosure. One of the anode tab or the cathode tab is electrically coupled to the battery enclosure. The other of the anode tab or the cathode tab is electrically insulated from the enclosure. The front face includes a protrusion portion that forms a step-like structure in the front face of the enclosure.

Abstract: Security devices and methods of securely coupling electronic devices and peripherals are provided. In one embodiment, a peripheral has a first coded magnet on a first surface of a first device. The first coded magnet has at least two different polarity regions on the first surface. A second coded magnet on a second surface of a second device is also provided. The first coded magnet is configured to securely provide data to a device associated with the second coded magnet, if the first and second coded magnets' patterns are keyed to one another.

Abstract: Connectors and methods of coupling electronic devices and cables are provided. In one embodiment, a connector has a first coded magnet on a first surface of a first device. The first coded magnet has at least two different polarity regions on the first surface. A second coded magnet on a second surface of a second device is also provided. The second coded magnet is configured to provide identifying information regarding the device on which it is located.

Abstract: A plug or connector including a coded magnet and an electrical contact. As the plug approaches a corresponding port, the coded magnet interacts with a magnet within the port. The interaction between the plug coded magnet and the port coded magnet provides a force to connect and/or align the plug with the port. Once the plug is received within the port, if a process is completed, the coded magnets polarities are altered to eject the plug from the port.

Abstract: A method of controlling pressure of a fuel gas in a fuel cell stack is disclosed. The method includes establishing a specification for a fuel gas/oxidant gas delta pressure vs. time value, operating the fuel cell stack, monitoring the fuel gas/oxidant gas delta pressure vs. time value and reducing stress resulting from excessive pressure of the fuel gas by implementing at least one of the following: (1) inducing the fuel cell stack to convert excess fuel gas into electrical current; (2) shutting off supply of the fuel gas to the fuel cell stack; and (3) and raising an operating pressure of the fuel cell stack when the fuel gas/oxidant gas delta pressure vs. time value strays beyond the specification.

Abstract: The various embodiment provide fastening devices, systems and methods that utilize two or more maxels in respective correlated magnetic structures provided in a first structure and at least one second structure to fasten or repulse the first structure to or from, as the case may be, the at least one second structure. In at least one embodiment, each maxel is programmable and may vary either or both the polarity and magnetic strength of the given maxel. The variance of the polarity and/or magnetic strength of the given maxel may be programmable and may be varied to attract or repulse a second magnetic structure which desirably also contains one or maxels forming a correlated magnetic structure.

Abstract: A plug or connector including a coded magnet and an electrical contact. As the plug approaches a corresponding port, the coded magnet interacts with a magnet within the port. The interaction between the plug coded magnet and the port coded magnet provides a force to connect and/or align the plug with the port. Once the plug is received within the port, if a process is completed, the coded magnets polarities are altered to eject the plug from the port.

Abstract: Security devices and methods of securely coupling electronic devices and peripherals are provided. In one embodiment, a peripheral has a first coded magnet on a first surface of a first device. The first coded magnet has at least two different polarity regions on the first surface. A second coded magnet on a second surface of a second device is also provided. The first coded magnet is configured to securely provide data to a device associated with the second coded magnet, if the first and second coded magnets' patterns are keyed to one another.

Abstract: Connectors and methods of coupling electronic devices and cables are provided. In one embodiment, a connector has a first coded magnet on a first surface of a first device. The first coded magnet has at least two different polarity regions on the first surface. A second coded magnet on a second surface of a second device is also provided. The second coded magnet is configured to provide identifying information regarding the device on which it is located.

Abstract: The disclosure identified as methods of mounting integrated circuits, including solar cells, to a substrate wherein the circuits are mounted prior to being singulated into discrete die. Once the semiconductor die sites or other circuits are formed on a wafer, the wafer will be attached, either whole, or divided into one or more multi-die site wafer segments, to a substrate. This attachment may be by conventional surface mount technology, for example. After such mounting, the individual die sites on the wafer segments will be singulated to form discrete die already mounted to the supporting substrate. The singulation may be preferably performed by laser dicing of the wafer segments.

Abstract: A method of controlling pressure of a fuel gas in a fuel cell stack is disclosed. The method includes establishing a specification for a fuel gas/oxidant gas delta pressure vs. time value, operating the fuel cell stack, monitoring the fuel gas/oxidant gas delta pressure vs. time value and reducing stress resulting from excessive pressure of the fuel gas by implementing at least one of the following: (1) inducing the fuel cell stack to convert excess fuel gas into electrical current; (2) shutting off supply of the fuel gas to the fuel cell stack; and (3) and raising an operating pressure of the fuel cell stack when the fuel gas/oxidant gas delta pressure vs. time value strays beyond the specification.

Abstract: A method of purging a fuel cell is disclosed. The method includes determining a running average current load on the fuel cell, a standard deviation of cell voltages of the fuel cell and/or a maximum change in cell voltage of the fuel cell. The fuel cell is purged if the running average current load exceeds an average current load standard, the standard deviation of cell voltages exceeds a standard deviation threshold value, or the maximum change in cell voltage exceeds a maximum allowed cell voltage change rate.

Abstract: A method of operating a fuel cell stack is disclosed. The method includes operating the fuel cell stack in accordance with a predetermined profile of fuel gas/oxidant gas delta pressure vs. time, monitoring a fuel gas/oxidant gas delta pressure vs. time value of the fuel cell stack and adjusting pressure of the fuel gas by consuming excess quantities of the fuel gas in the fuel cell stack when the fuel gas/oxidant gas delta pressure vs. time value of the fuel cell stack exceeds the predetermined profile.

Abstract: The disclosure identified as methods of mounting integrated circuits, including solar cells, to a substrate wherein the circuits are mounted prior to being singulated into discrete die. Once the semiconductor die sites or other circuits are formed on a wafer, the wafer will be attached, either whole, or divided into one or more multi-die site wafer segments, to a substrate. This attachment may be by conventional surface mount technology, for example. After such mounting, the individual die sites on the wafer segments will be singulated to form discrete die already mounted to the supporting substrate. The singulation may be preferably performed by laser dicing of the wafer segments.

Abstract: A fuel cell system having a fuel cell with an anode and a cathode wherein both the cathode and anode each have a flow path with an inflow and outflow. A gaseous source containing oxygen is connected to the inflow of the cathode flow path while a gaseous fuel source is connected to the inflow of the anode flow path. Upon shutdown of the fuel cell, a control system reduces the stoichiometric ratio at the anode to less than or equal to one to thereby deplete the oxygen from the gas at the cathode. A normally closed valve is fluidly connected between the cathode outflow and the anode inflow. The control system opens the valve upon shutdown of the fuel cell to thereby purge the fuel from the anode flow path with the oxygen depleted outflow from the cathode flow path.

Abstract: A method of operating a fuel cell stack is disclosed. The method includes operating the fuel cell stack in accordance with a predetermined profile of fuel gas/oxidant gas delta pressure vs. time, monitoring a fuel gas/oxidant gas delta pressure vs. time value of the fuel cell stack and adjusting pressure of the fuel gas by consuming excess quantities of the fuel gas in the fuel cell stack when the fuel gas/oxidant gas delta pressure vs. time value of the fuel cell stack exceeds the predetermined profile.

Abstract: A method of purging a fuel cell is disclosed. The method includes determining a running average current load on the fuel cell, a standard deviation of cell voltages of the fuel cell and/or a maximum change in cell voltage of the fuel cell. The fuel cell is purged if the running average current load exceeds an average current load standard, the standard deviation of cell voltages exceeds a standard deviation threshold value, or the maximum change in cell voltage exceeds a maximum allowed cell voltage change rate.