Abstract: A radio frequency identification device comprises an integrated circuit including a receiver, a transmitter, and a microprocessor. The receiver and transmitter together define an active transponder. The integrated circuit is preferably a monolithic single die integrated circuit including the receiver, the transmitter, and the microprocessor. Because the device includes an active transponder, instead of a transponder which relies on magnetic coupling for power, the device has a much greater range.

Abstract: A radio frequency identification device comprises an integrated circuit including a receiver, a transmitter, and a microprocessor. The receiver and transmitter together define an active transponder. The integrated circuit is preferably a monolithic single die integrated circuit including the receiver, the transmitter, and the microprocessor. Because the device includes an active transponder, instead of a transponder which relies on magnetic coupling for power, the device has a much greater range.

Abstract: The invention encompasses a device for sensing living organisms. Such device comprises a loop of conductive material extending over a substrate, and an insulative protective material over the loop of conductive material. The device further comprises a circuit which includes the conductive material as a first circuit component and which further includes a transponder as a second circuit component. The transponder is configured to emit a first signal if the loop of conductive material is continuous, and a second signal if the loop of conductive material is broken. The invention also encompasses a device for sensing termites. Such device comprises at least two wooden blocks separated by a gap, and a loop of conductive material within the gap. The device further comprises an insulative protective material over the loop of conductive material.

Abstract: In one aspect, the invention encompasses a device for sensing a change in an environment proximate the device. The device includes a planar circuit of conductive material extending along a first plane and comprising at least two sub-circuits which are in parallel electrical configuration relative to one another. The conductive material comprises two ends. The sub-circuits are configured to be broken upon the change in the environment. The device further includes a pair of prongs. A first of the pair of prongs extends from one of the two ends of the conductive material, and a second of the pair of prongs extends from an other of the two ends of the conductive material. The first and second prongs extend along the first plane. Additionally, the device includes a circuit support having circuitry supported thereby and a pair of orifices extending therethrough. The prongs extend through the orifices to electrically connect the circuitry supported by the circuit support to the planar circuit of conductive material.

Abstract: A radio frequency identification device comprises an integrated circuit including a receiver, a transmitter, and a microprocessor. The receiver and transmitter together define an active transponder. The integrated circuit is preferably a monolithic single die integrated circuit including the receiver, the transmitter, and the microprocessor. Because the device includes an active transponder, instead of a transponder which relies on magnetic coupling for power, the device has a much greater range.

Abstract: The invention includes methods for forming integrated circuits within substrates, and embedded circuits. In one aspect, the invention includes a method of forming an integrated circuit within a substrate comprising: a) providing a recess in a substrate; b) printing an antenna within the recess; and c) providing an integrated circuit chip and a battery in electrical connection with the antenna.

Abstract: Methods of forming electrically conductive interconnections and electrically interconnected substrates are described. In one implementation, a first substrate having an outer surface is provided and a layer of material is formed thereover. Openings are formed within the layer of material and conductive masses are formed within the openings. A second substrate having conductive interconnect surfaces is provided. The conductive interconnect surfaces are then contacted with the conductive masses and deformed thereby. In one aspect, the interconnect surfaces are deformed in part by portions of the layer of material proximate the conductive masses. In another aspect, the layer of material is removed and the interconnect surfaces are deformed by the conductive masses themselves.

Abstract: Thin-profile battery circuits and constructions, and in particular button-type battery circuits and constructions and methods of forming the same are described. In one implementation, a substrate is provided having an outer surface with a pair of spaced electrical contact pads thereon. At least two thin-profile batteries are conductively bonded together in a stack having a lowermost battery and an uppermost battery. The batteries include respective positive and negative terminals. The lowermost battery has one of its positive or negative terminals adhesively bonded to one of the pair of electrical contact pads while the uppermost battery has one of its positive or negative terminals electrically connected to the other of the pair of electrical contact pads. The batteries can be provided into parallel or series electrical connections.

Abstract: The present invention teaches a method of manufacturing an enclosed transceiver, such as a radio frequency identification (“RFID”) tag. Structurally, in one embodiment, the tag comprises an integrated circuit (IC) chip, and an RF antenna mounted on a thin film substrate powered by a thin film battery. A variety of antenna geometries are compatible with the above tag construction. These include monopole antennas, dipole antennas, dual dipole antennas, a combination of dipole and loop antennas. Further, in another embodiment, the antennas are positioned either within the plane of the thin film battery or superjacent to the thin film battery.

Abstract: The invention encompasses an electrical apparatus. Such apparatus includes RFID circuitry on a first substrate, and sensor circuitry on a second substrate. A receiving structure is associated with one of the RFID circuitry and the sensor circuitry, and at least one connecting structure is associated with the other of the RFID circuitry and the sensor circuitry. The at least one connecting structure is removable received within the receiving structure. The invention also encompasses a method of forming an electrical apparatus. A first substrate and a second substrate are provided. The first substrate has RFID circuitry thereon, and the second substrate has sensing circuitry thereon. A receptacle is joined with one of the RFID circuitry and the sensor circuitry, and has at least one orifice extending therein. At least one prong is joined with the other of the RFID circuitry and the sensor circuitry.

Abstract: The invention encompasses an electrical apparatus. Such apparatus includes RFID circuitry on a first substrate, and sensor circuitry on a second substrate. A receiving structure is associated with one of the RFID circuitry and the sensor circuitry, and at least one connecting structure is associated with the other of the RFID circuitry and the sensor circuitry. The at least one connecting structure is removable received within the receiving structure. The invention also encompasses a method of forming an electrical apparatus. A first substrate and a second substrate are provided. The first substrate has RFID circuitry thereon, and the second substrate has sensing circuitry thereon. A receptacle is joined with one of the RFID circuitry and the sensor circuitry, and has at least one orifice extending therein. At least one prong is joined with the other of the RFID circuitry and the sensor circuitry.

Abstract: An amplifier powered by a selectively engageable voltage source and a method for operating the amplifier. The amplifier includes first and second electrodes for receiving an input signal to be amplified. The first and second electrodes are adapted to be respectively connected to coupling capacitors. The amplifier also includes a differential amplifier having inputs respectively connected to the first and second electrodes, and having an output. The amplifier additionally includes selectively engageable resistances coupled between the voltage source and respective inputs of the differential amplifier and defining, with the coupling capacitors, the high pass characteristics of the circuit. The amplifier further includes second selectively engageable resistances coupled between the voltage source and respective inputs of the differential amplifier.

Abstract: Thin-profile battery circuits and constructions, and in particular button-type battery circuits and constructions and methods of forming the same are described. In one implementation, a substrate is provided having an outer surface with a pair of spaced electrical contact pads thereon. At least two thin-profile batteries are conductively bonded together in a stack having a lowermost battery and an uppermost battery. The batteries include respective positive and negative terminals. The lowermost battery has one of its positive or negative terminals adhesively bonded to one of the pair of electrical contact pads while the uppermost battery has one of its positive or negative terminals electrically connected to the other of the pair of electrical contact pads. The batteries can be provided into parallel or series electrical connections.

Abstract: The invention encompasses an electrical apparatus. Such apparatus comprises a first substrate having first circuitry thereon. The first circuitry has a terminal extending therefrom, and the terminal defines a first electrical node. The apparatus further comprises a first dielectric material covering a predominate portion of the first circuitry and not covering the first electrical node. Additionally, the apparatus comprises a second substrate having second circuitry thereon. The second circuitry has a terminal extending therefrom, and such terminal defines a second electrical node. A second dielectric material covers a predominate portion of the second circuitry, but does not cover the second electrical node. The second substrate comprises a different material than the first substrate. A portion of the second substrate is over a portion of the first substrate to define an overlap between the first and second substrates.

Abstract: A method of manufacturing and testing an electronic circuit, the method comprising forming a plurality of conductive traces on a substrate and providing a gap in one of the conductive traces; attaching a circuit component to the substrate and coupling the circuit component to at least one of the conductive traces; supporting a battery on the substrate, and coupling the battery to at least one of the conductive traces, wherein a completed circuit would be defined, including the traces, circuit component, and battery, but for the gap; verifying electrical connections by performing an in circuit test, after the circuit component is attached and the battery is supported; and employing a jumper to electrically close the gap, and complete the circuit, after verifying electrical connections.

Abstract: The present invention provides an apparatus and method of resetting an electric device. One method according to the present invention includes providing an electrical device including a power supply and an electrical component; providing an interconnect; electrically coupling the power supply and the electrical component using the interconnect; shorting the power supply of the electrical device following the coupling; removing the short; and applying power from the power supply to the electrical component via the interconnect. Another method according to the present invention includes providing a substrate; supporting a power supply using the substrate; supporting an electrical component using the substrate; coupling the power supply and the electrical component using an interconnect; temporarily shorting the power supply; and applying power via the interconnect to the electrical component using the power supply.

Abstract: The present invention teaches a method of manufacturing an enclosed transceiver, such as a radio frequency identification (“RFID”) tag. Structurally, in one embodiment, the tag comprises an integrated circuit (IC) chip, and an RF antenna mounted on a thin film substrate powered by a thin film battery. A variety of antenna geometries are compatible with the above tag construction. These include monopole antennas, dipole antennas, dual dipole antennas, a combination of dipole and loop antennas. Further, in another embodiment, the antennas are positioned either within the plane of the thin film battery or superjacent to the thin film battery.

Abstract: The invention encompasses an electrical apparatus. Such apparatus comprises a first substrate having first circuitry thereon. The first circuitry has a terminal extending therefrom, and the terminal defines a first electrical node. The apparatus further comprises a first dielectric material covering a predominate portion of the first circuitry and not covering the first electrical node. Additionally, the apparatus comprises a second substrate having second circuitry thereon. The second circuitry has a terminal extending therefrom, and such terminal defines a second electrical node. A second dielectric material covers a predominate portion of the second circuitry, but does not cover the second electrical node. The second substrate comprises a different material than the first substrate. A portion of the second substrate is over a portion of the first substrate to define an overlap between the first and second substrates.

Abstract: A method of manufacturing and testing an electronic circuit, the method comprising forming a plurality of conductive traces on a substrate and providing a gap in one of the conductive traces; attaching a circuit component to the substrate and coupling the circuit component to at least one of the conductive traces; supporting a battery on the substrate, and coupling the battery to at least one of the conductive traces, wherein a completed circuit would be defined, including the traces, circuit component, and battery, but for the gap; verifying electrical connections by performing an in circuit test, after the circuit component is attached and the battery is supported; and employing a jumper to electrically close the gap, and complete the circuit, after verifying electrical connections.

Abstract: Electronic apparatus, battery powerable apparatus, and radio frequency communication devices are disclosed. In but one implementation, an electronic apparatus comprises a substrate having a component mounted thereto. An encapsulant mass is received over and adheres to the gasifiable component and to the substrate. An opening is formed through the substrate and extends to the encapsulant mass. In another considered implementation, an electronic apparatus comprises a substrate having a component mounted thereto, with the component comprising a lateral periphery. An encapsulant mass is received over and adheres to the gasifiable component and to the substrate. An opening extends through the substrate from a location proximate the component within a region bounded by the component lateral periphery to externally of the substrate.