Systems and methods for the identification, powering and control of products and product packaging. The systems can include a point of sale display having a contactless power supply. The contactless power supply can provide a source of wireless power for products and product packaging. The products
Systems and methods for the identification, powering and control of products and product packaging. The systems can include a point of sale display having a contactless power supply. The contactless power supply can provide a source of wireless power for products and product packaging. The products and product packaging can include light emitting diodes, e-ink displays and printed speaker circuits that activate as the operating frequency of the contactless power supply varies. Other embodiments include product level sensors, inductive reader networks, printed temperature sensors, product alignment systems, passive identification circuits and methods for controlling operation of the same.
대표청구항▼
1. A product sensor for use with an inductive reader adapted to generate a time-varying electromagnetic field, the product sensor comprising: a storage device for a product;a product sensor circuit separate from the inductive reader and supported by the storage device and including a secondary coil
1. A product sensor for use with an inductive reader adapted to generate a time-varying electromagnetic field, the product sensor comprising: a storage device for a product;a product sensor circuit separate from the inductive reader and supported by the storage device and including a secondary coil electrically coupled to a variable impendence element; anda heater element adapted to heat the product in response to the time-varying electromagnetic field,wherein the impedance of the variable impedance element varies in proportion to a characteristic of the product, andwherein the product sensor circuit has a reflected impedance in response to the time-varying electromagnetic field that varies as a function of the impedance of the variable impedance element, such that the characteristic of the product can be determined remotely by the inductive reader based on the reflected impedance of the product sensor circuit. 2. The product sensor of claim 1 wherein the variable impedance element includes one of a variable resistor, a variable capacitor and a variable inductor. 3. The product sensor of claim 1 wherein: the product comprises a plurality of loose articles defining a weight; andthe characteristic includes the weight of the plurality of loose articles in the storage device. 4. The product sensor of claim 1 wherein: the product comprises a liquid defining a volume; andthe characteristic includes the volume of the liquid in the storage device. 5. The product sensor of claim 1 wherein: the product comprises a liquid defining a volume; andthe characteristic includes the temperature of the liquid in the storage device. 6. The product sensor of claim 1 wherein the heater element is formed from a ferromagnetic material. 7. The product sensor of claim 1 further including an inductive element electrically connected to the heater element for providing a source of electrical power to the heater element. 8. The product sensor of claim 1 wherein the variable impedance element is a thermistor and the characteristic is the product temperature, and wherein the product is adapted to be heated in response to the product temperature being below a desired temperature as measured by the thermistor. 9. The product sensor of claim 1 wherein the product sensor circuit includes a series resonant capacitor. 10. The product sensor of claim 1 wherein the storage device includes a base and an upward extending sidewall defining a storage space for the product. 11. The product sensor of claim 1 further including a product identification circuit supported by the storage device, the product identification circuit defining an inductive identification profile. 12. The product sensor of claim 11 wherein the product identification circuit includes a plurality of isolated resonant circuits each defining a resonant frequency. 13. The product sensor of claim 12 wherein each of the plurality of isolated resonant circuits includes a switch to vary the resonant frequency of the corresponding isolated resonant circuit. 14. The product sensor of claim 13 wherein each of the plurality of isolated resonant circuits includes an inductive element electrically coupled to a resistive element, wherein the switch is operable to short the resistive element. 15. A product sensor system comprising: an inductive reader including a primary tank circuit, the inductive reader being adapted to generate a time-varying electromagnetic field and adapted to determine a characteristic of a product based on an reflected impedance of a product sensor circuit,wherein the product sensor circuit includes an inductive element electrically coupled to an impedance element defining a variable impedance, wherein the variable impedance of the impedance element varies in proportion to the characteristic of the product, such that the characteristic of the product can be determined by the product sensor system based on the reflected impedance of the product sensor circuit, andwherein the product sensor circuit is included on a support device for the product and is separate from the inductive reader, the support device including a heater element adapted to heat the product in response to the time-varying electromagnetic field. 16. The product sensor system of claim 15 wherein the inductive reader is adapted to transmit the determined characteristic to a hub that is remote from the inductive reader and the support device. 17. The product sensor system of claim 15 wherein: the product comprises a plurality of loose articles defining a weight; andthe characteristic includes the weight of the plurality of loose articles in the support device. 18. The product sensor system of claim 15 wherein: the product comprises a liquid defining a volume; andthe characteristic includes the volume of the liquid in the support device. 19. The product sensor system of claim 18 wherein the liquid is at least partially conductive. 20. The product sensor system of claim 15 wherein: the product comprises a liquid defining a volume; andthe characteristic includes the temperature of the liquid in the support device. 21. The product sensor system of claim 15 wherein the impedance element includes one of a variable capacitor, a variable inductor and a variable resistor. 22. The product sensor system of claim 15 wherein the heater element is formed from a ferromagnetic material. 23. The product sensor system of claim 15 further including a product identification circuit supported by the support device, the product identification circuit defining an inductive identification profile. 24. The product sensor system of claim 23 wherein the product identification circuit includes a plurality of isolated resonant circuits each defining a resonant frequency. 25. The product sensor system of claim 24 wherein each of the plurality of isolated resonant circuits includes a switch to vary the resonant frequency of the corresponding isolated resonant circuit. 26. The product sensor system of claim 25 wherein each of the plurality of isolated resonant circuits includes an inductive element electrically coupled to a resistive element, wherein the switch is operable to short the resistive element. 27. The product sensor system of claim 23 wherein the inductive reader is adapted to generate a time varying current in the primary tank circuit having a frequency selected as a function of the inductive identification profile. 28. A method for forming a product sensor for use with an inductive reader, comprising: providing a product sensor circuit including an inductive element electrically coupled to an impedance element defining a variable impedance;providing a support device for a product defining a variable characteristic;providing a heater element adapted to heat the product in response to a time-varying electromagnetic field; andjoining the product sensor circuit and the heater element to the support device, wherein the impedance of the impedance element varies in proportion to the characteristic of the product in response to the time-varying electromagnetic field, wherein the product sensor circuit has a reflected impedance that varies as a function of the impedance of the impedance element, such that the characteristic can be determined remotely by the inductive reader based on the reflected impedance. 29. The method according to claim 28 further comprising adding the product to the support device. 30. The method according to claim 28 further comprising defining with the support device a base and a sidewall. 31. The method according to claim 28 further comprising forming the heater element from a ferromagnetic material. 32. A product monitoring system for a point of sale display, comprising: an inductive reader supported by the point of sale display and including a primary tank circuit, the inductive reader being adapted to detect a change in the cumulative reflected impedance of a plurality of product containers supported by the point of sale display corresponding to a change in a characteristic of power in the primary tank circuit in response to at least one of (1) the addition of a product container including an inductive circuit having an impedance element to the point of sale display and (2) the removal of one of the plurality of product containers including an inductive circuit having an impedance element from the point of sale display, wherein the impedance element is separate from the inductive reader. 33. The product monitoring system of claim 32 wherein the point of sale display comprises a shelving unit to slideably support a plurality of product containers. 34. The product monitoring system of claim 33 wherein the shelving unit defines a depth, the primary tank circuit including a primary coil extending substantially along the depth of the shelving unit. 35. The product monitoring system of claim 33 wherein the shelving unit defines a length, the primary tank circuit including a primary coil extending substantially along the length of the shelving unit. 36. The product monitoring system of claim 32 wherein the characteristic of power includes one of voltage, current and phase. 37. The product monitoring system of claim 32 wherein the inductive reader is adapted to detect a decrease in a reflected cumulative impedance of the plurality of product containers in response to removal of one of the plurality of product containers from the point of sale display. 38. The product monitoring system of claim 32 wherein the inductive reader is adapted to detect an increase in a reflected cumulative impedance of the plurality of product containers in response to the addition of a product container to the point of sale display. 39. The product monitoring system of claim 32 wherein the inductive reader is adapted to transmit information based on the addition or removal of a product container to a central hub. 40. The product monitoring system of claim 39 wherein the central hub includes a memory adapted to maintain historical product inventory levels.
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