Abstract: A magnetic strip card includes a partial encrypted card payload encrypted with a long shared key to provide a final encrypted payload. A method for encoding the magnetic strip card includes encrypting a card payload with a code key of a access controls with a short key of the access control to generate a partial encrypted payload and encrypting the partial encrypted payload with a long shared key to provide a final encrypted payload.

Abstract: A HVAC management system includes a space having an atmospheric condition to be controlled. Also included are air manipulation components to alter the atmospheric condition of the space. Further included is a sensor assembly located proximate the space for approximating a number of occupants present in the space based on a number of mobile devices located within the space. The sensor assembly includes a receiver capable of detecting communication data associated with a mobile device. The HVAC management system yet further includes a controller in operative communication with the air manipulation components and the sensor assembly, the controller receiving information from the sensor assembly comprising temperature data and the number of mobile devices, the controller controlling the air manipulation components based on the information received from the sensor assembly.

Abstract: Embodiments are directed to simulating an operation of a mechanical lock in an electronic context, comprising: applying a contactless wireless credential to a lock, authenticating the credential, unlocking the lock to provide access to a resource protected by the lock based on having authenticated the credential, determining a security level associated with the lock, and conditionally capturing the credential based on the security level.

Abstract: A magnetic communication system for a gas turbine engine may include a sensor coupled to a microcontroller. A low frequency radio-frequency identification integrated chip may be coupled to the microcontroller. A first coupling circuit may be coupled to the low frequency radio-frequency identification integrated chip and may include a first coil winding wound within a first core. The first coil winding operatively associated with a low frequency magnetic flux.

Abstract: A security sensor including a processor, communication module, antenna, and tamper detection circuit, wherein the sensor is configured to detect tampering based at least in part on a difference between an electrical characteristic of a first signal and the electrical characteristic of a second signal.

Abstract: An embedded magnetic identification assembly includes a base component formed of a material. Also included is a plurality of elements formed in an array at a surface of the base component, wherein the plurality of elements is formed of a magnetic material.

Abstract: A magnetic strip card includes a partial encrypted card payload encrypted with a long shared key to provide a final encrypted payload. A method for encoding the magnetic strip card includes encrypting a card payload with a code key of a access controls with a short key of the access control to generate a partial encrypted payload and encrypting the partial encrypted payload with a long shared key to provide a final encrypted payload.

Abstract: An embedded sensor apparatus for enabling wireless signal transmission while protecting an embedded sensor is disclosed. In various embodiments, an embedded sensor apparatus may comprise a substrate with a cavity, a wireless sensor embedded in the cavity of the substrate, a protective cover coupled to the wireless sensor, and a ferrite layer covering the protective cover. Further, the embedded sensor apparatus may comprise an electromagnetic reflector coupled between the wireless sensor and the substrate. In addition, the ferrite layer may be a ferrite plug, a deposited ferrite layer, or a combination thereof. Furthermore, in various embodiments, covering the protective cover with the ferrite layer may comprise depositing the ferrite layer on the protective cover using a cold spray process. In another embodiment, covering the protective cover with the ferrite layer may comprise depositing the ferrite layer on the protective cover using a thermal spray process.

Abstract: A sensor assembly for detecting open or closed state in windows and doors includes a passive infrared sensor configured to produce a change in an electrical signal based on a change in infrared radiation incident on the passive infrared sensor. A lens is operatively connected to the passive infrared sensor. At least a portion of the lens is configured to be mounted in an interface between a frame and a door or window mounted to open and close within the frame. The lens is configured to guide ambient infrared radiation to the passive infrared sensor at a first level when the door or window is closed and at a second level when the door or window is open or ajar.

Abstract: A security sensor including a processor, communication module, antenna, and tamper detection circuit, wherein the sensor is configured to detect tampering based at least in part on a difference between an electrical characteristic of a first signal and the electrical characteristic of a second signal.

Abstract: A sensing system may comprise a reader device including a primary magnetic coil, and a sensing device including a secondary magnetic coil and a sensing platform configured to acquire sensing data. The sensing system may further include a first part having the sensing device embedded therein. The reader device and the sensing device may be configured to communicate over a non-contact wireless interface using low frequency wireless power transfer.

Abstract: Embodiments are directed to a method comprising: providing, by a coil embedded in a structure of a rotor hub composed of a paramagnetic material, power to at least one sensor, and receiving, by the coil, data from the at least one sensor. Embodiments are directed to a system comprising: a coil embedded in a structure of a rotor hub composed of a paramagnetic material, and a plurality of sensors communicatively coupled to the coil and configured to receive power from the coil.

Abstract: A magnetic communication system for a gas turbine engine may include a sensor coupled to a microcontroller. A low frequency radio-frequency identification integrated chip may be coupled to the microcontroller. A first coupling circuit may be coupled to the low frequency radio-frequency identification integrated chip and may include a first coil winding wound within a first core. The first coil winding operatively associated with a low frequency magnetic flux.

Abstract: A sensor system includes a load-carrying element, an encoder structure, and a magnetic flux transducer. The load-carrying element is formed of substantially non-magnetic material, while the encoder structure is formed of magnetic material deposited via cold spray additive manufacturing within the load-carrying element. The magnetic flux transducer is disposed adjacent the load-carrying element to sense changes in magnetic flux caused by relative motion of the encoder structure.

Abstract: The present disclosure relates generally to a sensor including inductively coupled coils. Alignment of the coils may be maintained by constraining relative movement of the structures into which each of the coils is embedded. Alignment of the coils may be established by maintaining the transponder coil stationary while moving the reader coil with respect to the transponder coil and monitoring the current at the source supplying the reader coil. When the current at the source is at an extreme value (substantially maximized or minimized), the reader coil and the transponder coil are aligned. Additionally disclosed is an iterative process for designing coil geometries and resonant circuits for a sensor employing inductively coupled coils.

Abstract: Embodiments of the invention include a system including a spar of a wing having an outer body defining a hollow cavity in the outer body, a first communication assembly including a receiver and a first antenna connected to the receiver for receiving one or both of electrical signals and power, the first antenna located in the hollow cavity, and a second communication assembly. The second communication assembly includes a second antenna located in the hollow cavity and an electrical device. The second communication assembly is configured to transmit, by the second antenna, one or both of electrical signals and power through the hollow cavity to the first antenna.

Abstract: Embodiments are directed to simulating an operation of a mechanical lock in an electronic context, comprising: applying a contactless wireless credential to a lock, authenticating the credential, unlocking the lock to provide access to a resource protected by the lock based on having authenticated the credential, determining a security level associated with the lock, and conditionally capturing the credential based on the security level.

Abstract: Embodiments are directed to determining, by a processing device, a state of an internal power supply associated with a lock, and selecting, by the processing device, at least one of the internal power supply and an external power supply to power the lock based on the determination of the state of the internal power supply.

Abstract: An electrical load monitoring apparatus includes a first inductive coupling device, the first inductive coupling device is configured to receive electrical energy associated with an electrical conductor proximate thereto, and a processor in electrical communication with the first inductive coupling device, wherein the processor is configured to receive the electrical energy from the first inductive coupling device, configured to modulate a carrier wave signal in response to the received electrical energy, and configured to inject the modulated carrier wave signal into the electrical conductor.

Abstract: An embedded sensor apparatus for enabling wireless signal transmission while protecting an embedded sensor is disclosed. In various embodiments, an embedded sensor apparatus may comprise a substrate with a cavity, a wireless sensor embedded in the cavity of the substrate, a protective cover coupled to the wireless sensor, and a ferrite layer covering the protective cover. Further, the embedded sensor apparatus may comprise an electromagnetic reflector coupled between the wireless sensor and the substrate. In addition, the ferrite layer may be a ferrite plug, a deposited ferrite layer, or a combination thereof. Furthermore, in various embodiments, covering the protective cover with the ferrite layer may comprise depositing the ferrite layer on the protective cover using a cold spray process. In another embodiment, covering the protective cover with the ferrite layer may comprise depositing the ferrite layer on the protective cover using a thermal spray process.