An electrically passive device and method for in-situ acoustic emission, and/or releasing, sampling and/or measuring of a fluid or various material(s) is provided. The device may provide a robust timing mechanism to release, sample and/or perform measurements on a predefined schedule, and, in various embodiments, emits an acoustic signal sequence(s) that may be used for triangulation of the device position within, for example, a hydrocarbon reservoir or a living body.

A power cable (10) includes at least one electrical conductor (12) and at least one interstice (14) in the vicinity of the electrical conductor (12). The cable (10) further has at least one electronic device (18) for radiofrequency identification and at least one tube (16) arranged in the at least one interstice (14) and containing the electronic device (18) for radiofrequency identification.

Disclosed are methods and apparatus for identifying non-metallic subterranean structures using amorphous metal markers associated with the structures. Some examples will include the amorphous metal in the form of one or more sections of an amorphous metal foil within a protective enclosure sufficient to physically isolate the amorphous metal foil from the surrounding Earth. The amorphous metal foil and enclosure may be in the form of a tape which either will be secured to, or placed proximate the subterranean structure, which may be, for example, a pipe or conduit, or other non-metallic structure.

Disclosed are methods and apparatus for identifying non-metallic subterranean structures using amorphous metal markers associated with the structures. Some examples will include the amorphous metal in the form of one or more sections of an amorphous metal foil within a protective enclosure sufficient to physically isolate the amorphous metal foil from the surrounding Earth. The amorphous metal foil and enclosure may be in the form of a tape which either will be secured to, or placed proximate the subterranean structure, which may be, for example, a pipe or conduit, or other non-metallic structure.

A bin for use in a security checkpoint can include a receptacle surface, sidewalls, a lip provided on the sidewalls, and a geometrical marker. The geometrical marker is radiographically, visually, and tactilely detectable on the lip of one side of the bin. The geometrical marker includes a plurality of tag elements.

A bin for use in a security checkpoint can include a receptacle surface, sidewalls, a lip provided on the sidewalls, and a geometrical marker. The geometrical marker is radiographically, visually, and tactilely detectable on the lip of one side of the bin. The geometrical marker includes a plurality of tag elements.

Applicants have discovered that an inexpensive marker tape can be made from some of the components used in applicants Signal Tape disclosed in PCT/US2017/050405. This marker tape, called Spartan Marker Tape, has elongated upper and lower protective layers made from a thermoplastic material which are laminated together with a locating device inside the laminated layers. Various locating devices may be used in the Spartan Marker Tape, such as conventional RF or RFID tags. In addition, magnetic tags, or radioactive tags may be used. Of course, classis marker wire may also be used as a locating device.

Applicants have discovered that an inexpensive marker tape can be made from some of the components used in applicants Signal Tape disclosed in PCT/US2017/050405. This marker tape, called Spartan Marker Tape, has elongated upper and lower protective layers made from a thermoplastic material which are laminated together with a locating device inside the laminated layers. Various locating devices may be used in the Spartan Marker Tape, such as conventional RF or RFID tags. In addition, magnetic tags, or radioactive tags may be used. Of course, classis marker wire may also be used as a locating device.

Systems and methods for enhanced directionality for portal detector stations are provided. The systems include a portal detector station, an overhead detector station, a controller operatively coupled thereto. In embodiments, the controller analyzes read events detected by the portal detector station to determine a set of RFID tags included in a pallet of objects. The controller also analyzes read events detected by the overhead detector station to determine a direction of travel for the RFID tags included in the set of RFID tags and/or to detect stray read events that resulted in RFID tags being erroneously included in the set of RFID tags.

One aspect of the invention relates to a method of detecting a spatial orientation of a transducer by a handheld optical scanning device. The method comprises steps of providing a first spatial orientation feature on at least a first outer housing surface of the transducer and arranging a handheld optical scanning device in a sightline of the first spatial orientation feature at a selected spatial orientation relative to the first outer surface of the transducer housing. The method comprises further steps of identifying the first spatial orientation feature, detecting a spatial orientation of the handheld scanning device in a predetermined coordinate reference system and determining a spatial orientation of the transducer in the predetermined coordinate reference system.