Abstract: Systems and methods for monitoring a plurality of assets using a plurality of location tags are provided. The plurality of assets includes a conveyor system and at least one other asset. At least a subset of the location tags is positioned at a fixed position along the conveyor system, and at least one location tag is positioned at the at least one other asset. Each location tag includes at least one environmental sensor and a communication interface. The communication interface is configured to transmit a sensor signal to a network system and at least one information signal to a mobile receiver. The mobile receiver moves with respect to the conveyor system such that the distance between the mobile receiver and the subset of the location tags continuously changes, and a position of the mobile receiver is determined based on a signal strength of the information signal.

Abstract: A can cutting device that has a main body and a can support assembly coupled to the main body. The can support assembly has a shaft that extends along a longitudinal shaft axis, an eccentrically mounted mandrel that extends along a longitudinal mandrel axis parallel to the longitudinal shaft axis, and a cutter coupled to the main body having a cutting surface. The can is positionable in a mounted position such that the can is rotatable about a can axis of rotation, the cutting surface is positional to contact the portion of the can body supported by the mandrel at the cutting location, and when the cutting surface is in contact with the portion of the can body supported by the mandrel at the cutting location and the can is rotated about the can axis of rotation, the cutter cuts the portion of the can body at the cutting location.

Abstract: A can cutting device having a main body and a can support assembly coupled to the main body. The can support assembly having a shaft that extends along a longitudinal shaft axis, an eccentrically mounted mandrel that extends along a longitudinal mandrel axis parallel to the longitudinal shaft axis, and a cutter coupled to the main body having a cutting surface. The can is positionable in a mounted position such that the can is rotatable about a can axis of rotation, the cutting surface is positionable to contact the portion of the can body supported by the mandrel at the cutting location, and when the cutting surface is in contact with the portion of the can body supported by the mandrel at the cutting location and the can is rotated about the can axis of rotation, the cutting surface cuts the portion of the can body at the cutting location.

Abstract: A system and method of measuring and analyzing an object within a rotating shell is provided. The system can include a receptacle defining an interior storage chamber; at least one sensor, the at least one sensor being contained within the interior storage chamber, the at least one sensor having a fixed spatial relationship to the receptacle; and at least one processor configured for processing the measurement data. The at least one sensor can include a gyroscope for measuring angular velocity of the receptacle over a duration of time and generating measurement data indicative of the angular velocity over the duration of time. In some embodiments, the method involves determining a position of the receptacle within the rotating shell. In some embodiments, the receptacle includes heat resistant material capable of shielding electronics contained within the interior storage chamber from temperatures that exceed a maximum temperature rating of the electronics.

Abstract: Various systems and methods for providing automated feedback to a user using a shoe insole assembly are disclosed. In one example embodiment, a shoe insole assembly shaped to be positioned within a footwear and shaped to conform to the contour of the bottom of a human foot when placed within the footwear is provided. The shoe insole assembly comprises a pressure-sensing circuit for determining a pressure profile exerted on the shoe insole assembly by the human foot and for generating data signals corresponding to the pressure profile, a control circuit for processing the data signals received from the pressure-sensing circuit, and housing for encapsulating the pressure-sensing circuit and the control circuit. The processed signals are used to generate output signals that provide feedback to the user based on the pressure exerted on the shoe insole assembly. The shoe insole assembly of the various embodiments illustrated herein is an integral structure.

Abstract: A system and method of measuring and analyzing an object within a rotating shell is provided. The system can include a receptacle defining an interior storage chamber; at least one sensor, the at least one sensor being contained within the interior storage chamber, the at least one sensor having a fixed spatial relationship to the receptacle; and at least one processor configured for processing the measurement data. The at least one sensor can include a gyroscope for measuring angular velocity of the receptacle over a duration of time and generating measurement data indicative of the angular velocity over the duration of time. In some embodiments, the method involves determining a position of the receptacle within the rotating shell. In some embodiments, the receptacle includes heat resistant material capable of shielding electronics contained within the interior storage chamber from temperatures that exceed a maximum temperature rating of the electronics.

Abstract: Various systems and methods for providing automated feedback to a user using a shoe insole assembly are disclosed. In one example embodiment, a shoe insole assembly shaped to be positioned within a footwear and shaped to conform to the contour of the bottom of a human foot when placed within the footwear is provided. The shoe insole assembly comprises a pressure-sensing circuit for determining a pressure profile exerted on the shoe insole assembly by the human foot and for generating data signals corresponding to the pressure profile, a control circuit for processing the data signals received from the pressure-sensing circuit, and housing for encapsulating the pressure-sensing circuit and the control circuit. The processed signals are used to generate output signals that provide feedback to the user based on the pressure exerted on the shoe insole assembly. The shoe insole assembly of the various embodiments illustrated herein is an integral structure.