Abstract: The present disclosure provides an optical sensor module. An example optical sensor module comprises: a light-emitting device; a module cap adapted to at least partially cover the light-emitting device, the module cap comprising a first opening located over the light-emitting device; at least a conductive strip assembled with, or included in, the module cap; a glass positioned in the first opening and/or covering the first opening, and adapted to transmit light signals emitted by the light-emitting device, the glass including a conductive trace; and at least a conductive wire formed by wire bonding, the at least one conductive wire electrically connecting the conductive trace to the at least one conductive strip.

Abstract: Example embodiments of the present disclosure provide an optical module sensor. An example optical module sensor may include an optical radiation-emitting device, a reference, an optical radiation receiver positioned, an electromagnetic interference shield, and a housing cap. The housing cap may include a barrier wall positioned such that the housing cap defines a transmission cavity and a receiving cavity. The optical radiation-emitting device and the reference sensor may be positioned within the transmission cavity and the optical radiation receiver may be positioned within the receiving cavity. The housing cap may include an attenuation wall positioned between the reference sensor and the optical radiation receiver.

Abstract: The present disclosure provides an optical sensor module. An example optical sensor module includes a light-emitting device; a light-receiving sensor; and a module cap adapted to at least partially cover the light-emitting device and the light-receiving sensor, the module cap being a molded cap, the molded cap being formed of a molding material comprising electrically conductive particles dispersed therein for providing electromagnetic interference shielding.

Abstract: An example apparatus and optical emission device for preventing the transmission of electromagnetic radiation to and from targeted electrical components of an electronic device are provided. The example apparatus may include an optical emissions component electrically connected to a target electrical portion and configured to generate an optical output. The example apparatus may further include a wire bond electromagnetic interference cage configured to block the passage of electromagnetic emissions. The wire bond electromagnetic interference cage may include a plurality of bond wires, wherein each bond wire is electrically coupled to an electrical ground, and wherein the wire bond electromagnetic interference cage overlays at least a portion of the target electrical portion. In addition, the wire bond electromagnetic interference cage may further define an electromagnetic interference cage opening through which the optical output passes.

Abstract: “The present disclosure provides methods and systems for sequencing proteins. One or more methods disclosed herein may use linkers having an amino acid-reactive group and an additional reactive moiety that may be used to couple a polymerizable molecule. The linker may couple to a polymerizable molecule and an amino acid of a peptide and a capture moiety via the polymerizable molecule, followed by cleavage of the amino acid from the peptide. Further processing and analysis may be conducted using, for example, nanopores or nanogaps.

Abstract: The present disclosure provides methods and systems for sequencing proteins. One or more methods disclosed herein may use linkers having an amino acid-reactive group and an additional reactive moiety that may be used to couple a polymerizable molecule. The linker may couple to a polymerizable molecule and an amino acid of a peptide and a capture moiety via the polymerizable molecule, followed by cleavage of the amino acid from the peptide. Further processing and analysis may be conducted using, for example, nanopores or nanogaps.

Abstract: Provided herein are methods and systems for sequencing proteins. One or more methods disclosed herein may use linkers comprising an amino acid-reactive group and an additional reactive moiety that may be used to couple a polymerizable molecule. The linker may couple to a polymerizable molecule and an amino acid of a peptide and a capture moiety via the polymerizable molecule, followed by cleavage of the amino acid from the peptide. Further processing and analysis may be conducted using, for example, nanopores or nanogaps.

Abstract: Provided herein are methods and systems for sequencing proteins. One or more methods disclosed herein may use linkers comprising an amino acid-reactive group and an additional reactive moiety that may be used to couple a polymerizable molecule. The linker may couple to a polymerizable molecule and an amino acid of a peptide and a capture moiety via the polymerizable molecule, followed by cleavage of the amino acid from the peptide. Further processing and analysis may be conducted using, for example, nanopores or nanogaps.

Abstract: A tether-based system for utilizing the aerostatic lift of a light-than-air balloon for the transport of payload across a wide area without having to translate the balloon along with the payload.