Patent Description:
Electronic Article Surveillance (EAS) systems typically operate in the high frequency (HF) range, nominally at <NUM>, while certain Radio Frequency Identification (RFID) systems operate in the ultra high frequency (UHF) range, nominally at <NUM>. EAS systems typically include a HF coil antenna coupled to a capacitive element that forms a resonant circuit configured to return a signal when excited by a nearby field at the resonant frequency of the EAS circuit elements. UHF RFID systems typically include a UHF antenna and/or tuning loop coupled to an RFID chip that powers the RFID chip when excited by a nearby field at the resonant frequency of the UHF antenna and internal capacitance of the RFID chip. The RFID chip sends a coded return signal when powered. Typically, EAS devices and RFID devices are used for different purposes and are manufactured and sold as separate items.

<CIT> relates to a Radio Frequency Identification (RFID) integrated circuit (IC) having a first circuit block electrically coupled to first and second antenna contacts. The first antenna contact is disposed on a first surface of the IC and the second antenna contact is disposed on a second surface of the IC different from the first surface. The first and second antenna contacts are electrically disconnected from each other.

<CIT> relates to an RFID tag that is foldable about a generally transverse fold line. The line divides the tag into two regions. One region has an RFID integrated circuit and areas of electrically conductive material. The other region has conductive areas that provide an efficient RFID antenna. In a folded configuration the areas are operatively associated with the integrated circuit while in the open configuration the areas are not functionally associated with the integrated circuit. Accordingly in the open configuration the tag is disabled or its RFID performance substantially degraded. The tag can be reversibly altered between the open and folded configurations.

The systems and methods disclosed herein are described in detail by way of examples and with reference to the FIGS. It will be appreciated that modifications to disclosed and described examples, arrangements, configurations, components, elements, apparatuses, devices methods, systems, etc. can suitably be made and may be desired for a specific application. In this disclosure, any identification of specific techniques, arrangements, etc. are either related to a specific example presented or are merely a general description of such a technique, arrangement, etc. Identifications of specific details or examples are not intended to be, and should not be, construed as mandatory or limiting unless specifically designated as such.

The present disclosure illustrates new modalities for straps for combined EAS and RFID circuits. The systems and methods disclosed herein describe various aspects of straps and antenna structures for combined EAS and RFID circuits. The claimed invention is defined by the independent claim. Particular embodiments are defined by the dependent claims.

EAS devices and RFID devices are generally designed for different functions and, therefore, are manufactured separately. For example, EAS devices are generally attached to items and are used to prevent theft of those items from stores by requiring deactivation of the EAS device at a point-of-sale terminal when purchased. RFID devices can be used for many different purposes including, for example, item identification, item tracking, and inventory. As can be appreciated, items can include both an EAS device and an RFID device to provide the respective benefits of both devices. For example, consumer goods can include both an EAS device and an RFID device to allow for theft protection and for inventory management.

Combining the functionality of an EAS device and an RFID device into a single device can provide several advantages. One advantage is that combining an EAS device and an RFID device into a single device reduces manufacturing and inventory costs required for multiple tags. Another advantage is that combining an EAS device and an RFID device into a single device reduces the number of devices that must be separately attached to each item or the number of customized supply chains applying different tags to items. This reduces the potential for damage to items that might be caused by numerous attachment points to an item. This also reduces the number of attached devices that might need to be removed by the consumer or merchant, potentially saving time and reducing labor costs. Yet another advantage of combining an EAS device and an RFID device into a single device is that the radio frequency elements can be purposefully isolated from one another to avoid interference. When separate EAS devices and RFID devices are in close proximity, it is possible for the radio frequency elements in one device to interfere with the function of the other device. A single combined device can be designed to reduce the likelihood of interference.

Turning to <FIG>, a strap structure <NUM> is illustrated. The strap structure <NUM> comprises a first coupling pad <NUM> and a second coupling pad <NUM>. An RFID chip <NUM> operating in the ultra high frequency (UHF) spectrum, for example at or near <NUM>, is connected to the strap structure <NUM>. The frequency of the RFID chip <NUM> presently set forth is not limited to any particular frequency. For instance, an RFID chip <NUM> may operate at <NUM>. In certain configurations, the RFID chip <NUM> can be connected via narrow sections <NUM> of the strap structure <NUM>. An inductive element, UHF tuning loop <NUM>, can be configured to provide a resonance with the capacitance of the RFID chip <NUM> in the UHF frequency range. The strap structure <NUM> can be directly coupled, or conductively coupled, to the UHF tuning loop <NUM>.

Referring also to <FIG>, a coil antenna <NUM> is coupled to the strap structure <NUM>. The coil antenna <NUM> comprises an inner coil end <NUM> and an outer coil end <NUM> that interface with the first coupling pad <NUM> and second coupling pad <NUM> respectively of the strap structure <NUM>. In a first configuration, as shown in <FIG>, the coil antenna <NUM> can be capacitively coupled to the strap structure <NUM>. In a second configuration, the coil antenna <NUM> can be conductively coupled to the strap structure <NUM>. The coil antenna <NUM>, due to its structure, can operate as a slot or pole type UHF antenna. In certain embodiments, an additional UHF antenna element <NUM> can be provided.

The coil antenna <NUM> can be configured such that a gap <NUM> is created between turns of the coil antenna <NUM>, allowing the UHF tuning loop <NUM> to be placed between the turns of the coil antenna <NUM> as illustrated in <FIG>. This can advantageously ensure that the metal of the coil antenna <NUM> does not pass directly under the UHF tuning loop <NUM> which could change the inductance of the UHF tuning loop <NUM> and could introduce unwanted losses, or otherwise interfere with the operation of the circuit.

The coil antenna <NUM> resonates with the total capacitance presented by the strap structure <NUM> via the UHF tuning loop <NUM>. The UHF tuning loop <NUM> can present a relatively low inductance on the order of about 20nH to about 30nH which is negligible at the desired resonant frequency for the coil antenna <NUM>. The desired resonant absorption frequency for EAS systems is approximately <NUM>. The UHF tuning loop <NUM> can therefore operate as a structure commonly described as a bridge.

A feature of EAS components is the ability to deactivate the EAS functionality of the circuit at a point of sale terminal when an item is purchased by a consumer. Typically this is achieved by exposing the circuit to a strong field at, or near, the circuit's resonant frequency. This exposure of the circuit at the resonant frequency causes a high current to flow in the conductors and an associated high voltage to be developed across the capacity components.

Referring now to <FIG>, an improved strap/bridge circuit <NUM> is disclosed. In the improved strap/bridge circuit <NUM>, the overlap between each of the coil ends of the antenna coil and the associated coupling pads can be configured to be different. In the example which helps to understand the claimed invention illustrated in <FIG>, the inner coil end <NUM> of the coil antenna can be configured to be smaller than the outer coil end <NUM> of the coil antenna. The first coupling pad <NUM> and second coupling pad <NUM> can be coupled to the inner coil end <NUM> and outer coil end <NUM> respectively via an adhesive that acts as a dielectric between the coil ends and coupling pads. The capacitance associated with the coil ends and coupling pads is proportional to the overlap area and is: <NUM>/Ctotal = <NUM>/C1 + <NUM>/C2 where C1 is the capacitance between the inner coil end <NUM> and the first coupling pad <NUM>, and C2 is the capacitance between the outer coil end <NUM> and the second coupling pad <NUM>.

Although the illustration of <FIG> shows changes in dimensions only for the coil ends, in other examples the sizes of one or more of the coil ends and/or one of more of the coupling pads can be configured to be different as would be understood in the art.

The circuit resonates at a resonant frequency that is determined by the inductance of the antenna coil and tuning coil, and the total capacitance determined by the configuration of the coil ends and coupling pads. When an electromagnetic field is presented to the circuit at or around the resonant frequency, a common current flows through the capacitors C1 and C2. The voltage across each of the capacitors C1 and C2 is inversely proportional to the capacitance of each. Therefore, by minimizing C1 and maximizing C2 it is possible to develop a higher voltage across C1 than C2. In this way, the highest possible voltage for a given field strength is developed across C1. The dielectric (adhesive) used to couple the coil end to the coupling pad can be formulated to undergo a dielectric breakdown at a threshold breakdown voltage that is lower than the voltage presented at C1 but higher than the voltage presented at C2. The breakdown voltage can be selected by changing the dielectric constant, the conductivity, thickness, or other suitable property of the dielectic (adhesive) so as to make any resonance of the circuit undetectable by an EAS gate reader system.

To reduce the voltage at which a capacitor breaks down, one or more points of separation can be reduced between capacitor places. This can be achieved by embossing or otherwise mechanically modifying the metal layers of capacitor plates. Similarly, to reduce the breakdown voltage for C1 or C2, one or more points of separation can be reduced between a coil end and a coupling pad. Referring now to <FIG>, a structure <NUM> on the metal surface <NUM> of a coil end (and/or a coupling pad) can be made using a laser system. In such embodiments, a laser beam <NUM>, or another suitable means of causing ablation such as an electron beam, causes metal to evaporate at the impact point <NUM> of the laser beam <NUM>, that also melts adjacent metal <NUM> which is forced away and up by the pressure of the evaporating metal at the impact point <NUM>. This creates a sharp edged crater-like structure <NUM> based on the characteristics of the laser beam <NUM>, such as how the laser beam <NUM> is pulsed, the power incident at the impact point <NUM>, the wavelength, the metal composition, and other factors. In certain embodiments, multiple points on one or more metal surfaces <NUM> can be made to decrease the breakdown voltage.

Referring again the circuits of <FIG>, and <FIG>, in examples which help to understand the claimed invention the UHF tuning loop <NUM>, <NUM> can be configured to change properties when a high current flows through the UHF tuning loop <NUM>, <NUM>. In certain embodiments, the UHF tuning loop <NUM>, <NUM> can include a fuse type structure that causes the UHF tuning loop <NUM>, <NUM> to become an open circuit above a threshold AC current. For example, the UHF tuning loop <NUM>, <NUM> can become an open circuit when the EAS function of the circuit is de-activated. By opening the UHF tuning loop <NUM>, <NUM>, the tuning of the entire circuit can be changed, leading to a changed read range. For example, in certain embodiments, the read range can be greatly reduced or substantially eliminated. In other certain embodiments, the read range of the circuit could be increased by opening the UHF tuning loop <NUM>, <NUM>. ) Example fuse type structures can include, but are not limited to, polymers with conductive particles and/or structures that normally have a low resistance but which under localized heating caused by a high AC current are caused to expand non-reversibly and have a high resistance.

Referring now to <FIG>, a dual mode strap <NUM> is illustrated that is configured for both a UHF response and a resonance suitable for triggering an EAS gate. The dual mode strap <NUM> includes asymmetric coupling pads and includes a relatively large coupling pad <NUM> and a relatively small coupling pad <NUM> that are coupled to a UHF RFID chip <NUM>. Referring also to <FIG>, the large coupling pad <NUM> is configured to be large enough to support a first coupling area <NUM> and a second coupling area <NUM>. The large coupling pad <NUM> is configured to function as a bridge across the coil ends of an antenna coil with a defined capacitance set by the adhesive properties and the overlaps areas as describe above. The small coupling pad <NUM> is configured to support a third coupling area <NUM> for coupling to an additional UHF antenna element <NUM>. The dual mode strap <NUM> can therefore support both resonant absorption for EAS functionality and UHF RFID functionality as the UHF RFID chip <NUM> is coupled to the coil antenna at one end and a UHF RFID antenna at the other end. In certain configurations, the first coupling area <NUM>, the second coupling area <NUM>, and/or the third coupling area <NUM> can be a different size than the overlap area; for example the coupling area can be smaller than the overlap area as illustrated in <FIG>.

Referring now also to <FIG>, in certain examples which help to understand the claimed invention, the dual mode strap <NUM> of <FIG> can include a UHF tuning loop <NUM>. Because both coil ends of the coil antenna of <FIG> are coupled to the large coupling pad <NUM> (and not the small coupling pad <NUM>), the UHF tuning loop <NUM> can be positioned as shown in <FIG> so as to be offset from the coil antenna to avoid interference. As described above, the UHF tuning loop <NUM> can include a fuse type structure that causes the UHF tuning loop <NUM> to open circuit above a threshold AC current, for example when the EAS function of the circuit is de-activated.

Referring now also to <FIG>, in certain examples which help to understand the claimed invention, the first coupling point <NUM> and second coupling point <NUM> can be configured to be asymmetric in size so as to concentrate voltage at one of the coupling points (e.g., second coupling point <NUM>, as shown in <FIG>) for de-activating the circuit by exposing the circuit to a high strength field at the resonant frequency of the circuit.

Referring now to <FIG>, a modified coil antenna structure <NUM> is depicted. The modified coil antenna structure <NUM> is configured to have a large coil with a narrow gap width <NUM> between turns. This causes the coil antenna to act a sloop type antenna such that at UHF frequencies, the energy couples across the narrow gap width <NUM> to form a short at UHF frequencies, but which allows energy at HF frequencies to flow around the coil antenna turns normally. The coil antenna can include a wider gap width <NUM> for a portion of the coil antenna for UHF frequencies. A strap <NUM>, tuning loop <NUM>, and RFID chip <NUM> are included as described previously for other examples. The coupling between the turns can be enhanced by decreasing the gap width by, for example, laser cutting a narrow gap <NUM> as illustrated in <FIG>, and/or by increasing the relative edge-to-edge area between turns by cutting a curvilinear gap <NUM> (or cutting any suitable pattern) as illustrated in <FIG>.

Referring to <FIG>, a first embodiment of a foldover circuit <NUM> is presented. The foldover circuit <NUM> can be configured such that when the foldover circuit <NUM> is folded at a fold line <NUM>, coupling pad <NUM> of the strap <NUM> functions as a bridge for coil antenna <NUM>. Coupling pad <NUM> can be conductively coupled to a first coil end <NUM> of coil antenna <NUM>. When foldover circuit <NUM> is folded, coupling pad <NUM> can be capacitively coupled to second coil end <NUM> of coil antenna <NUM>, for example using a dielectric adhesive as described above. Similarly, an additional UHF antenna element <NUM> can be capacitively coupled to the strap <NUM> when the foldover circuit <NUM> is folded.

Referring to <FIG>, a second embodiment of a foldover circuit <NUM> is presented. Foldover circuit <NUM> can be configured such that when the foldover circuit <NUM> is folded at fold line <NUM>, a bridge portion <NUM> (first coupling pad) of the strap <NUM> contacts a first coil end <NUM> and a second coil end <NUM> of coil antenna <NUM>. The bridge portion <NUM> and coil ends <NUM>, <NUM> are capacitively coupled using a dielectric adhesive as described above. Similarly, an additional UHF antenna element <NUM> can be capacitively coupled to a UHF portion <NUM> (second coupling pad) of the strap <NUM> when the foldover circuit <NUM> is folded. The strap <NUM> and RFID chip <NUM> can be configured on one side of a substrate <NUM>, while the coil antenna <NUM> and UHF antenna element <NUM> can be configured on a second side of the substrate <NUM>. The substrate <NUM> can comprise any suitable material including, but not limited to, a paper, a card, a plastic such as PET, or a fabric such as nylon or polypropylene. The substrate <NUM> can be folded at fold line <NUM> and the two sides laminated together.

Claim 1:
A device, comprising:
a foldover circuit (<NUM>; <NUM>), folded at a fold line (<NUM>; <NUM>), the device being characterised in that it further comprises
a bridge portion (<NUM>; <NUM>) of a strap (<NUM>; <NUM>) that contacts a first coil end (<NUM>; <NUM>) and a second coil end (<NUM>; <NUM>) of a coil antenna (<NUM>; <NUM>) such that the bridge portion (<NUM>; <NUM>) and coil ends (<NUM>, <NUM>; <NUM>, <NUM>) are capacitively coupled using a dielectric adhesive;
and a UHF antenna element (<NUM>; <NUM>) that is coupled to a UHF portion (<NUM>) of the strap (<NUM>; <NUM>) when the foldover circuit (<NUM>; <NUM>) is folded.