The present invention provides systems and methods for transmitting and receiving information from a radio frequency (RF) transponder. A conductive adhesive connects an antenna in a non-metallized region to a metallized region. This feature transforms the entire metallized region of the radio frequency device (i.e., the remainder of the metallized material outside the non-metallized region) into an antenna.
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14. A radio frequency device comprising:
at least one base layer;
at least one metallized region disposed on the at least one base layer;
at least one non-metallized region;
at least one holographic image on the at least one non-metallized region;
at least one antenna on the at least one non-metallized region;
at least one radio frequency chip in the at least one base layer in communication with the at least one antenna; and
at least one electrical connection connecting the at least one antenna to the at least one metallized region such that the at least one metallized region acts as a second antenna or as a part of the one antenna.
1. A radio frequency device comprising:
at least one metallized region;
at least one non-metallized region;
at least one antenna on the at least one non-metallized region;
at least one radio frequency chip in electrical communication with the at least one antenna; and
at least one electrical connection connecting the at least one antenna to the at least one metallized region, wherein the at least one antenna is electrically interspersed between the radio frequency chip and the at least one metallized region, such that the at least one metallized region acts as a second antenna or as a part of the at least one antenna; and,
wherein the at least one metallized region is not in direct electrical communication with the at least one radio frequency chip.
16. A radio frequency device comprising:
at least one base layer;
at least one metallized region disposed on the at least one base layer;
at least one non-metallized region;
at least one holographic image in the at least one non-metallized region;
at least one antenna on the at least one non-metallized region;
at least one radio frequency chip on the at least one base layer in communication with the at least one antenna; and
at least one electrical connection connecting the at least one antenna to the at least one metallized region such that the at least one metallized region acts as a second antenna or as a part of the at least one antenna; and
whereby the at least one non-metallized region is created by demetallizing a portion of the at least one metallized region.
7. A radio frequency device comprising:
at least one base layer;
at least one metallized region disposed on the at least one base layer;
at least one non-metallized region;
at least one antenna on the at least one non-metallized region;
at least one radio frequency chip on the at least one base layer in electrical communication with the at least one antenna; and
at least one electrical connection connecting the at least one antenna to the at least one metallized region, wherein the at least one antenna is electrically interspersed between the radio frequency chip and the at least one metallized region, such that the at least one metallized region acts as a second antenna or as a part of the at least one antenna; and,
wherein the at least one metallized region is not in direct electrical communication with the at least one radio frequency chip.
11. A radio frequency device comprising:
at least one base layer;
at least one metallized region disposed on the at least one base layer;
at least one non-metallized region;
at least one holographic image;
at least one antenna on the at least one non-metallized region;
at least one radio frequency chip in the at least one base layer in communication with the at least one antenna; and
at least one electrical connection connecting the at least one antenna to the at least one metallized region, wherein the at least one antenna is electrically interspersed between the radio frequency chip and the at least one metallized region, such that the at least one metallized region acts as a second antenna or as a part of the at least one antenna; and,
wherein the at least one metallized region is not in direct electrical communication with the at least one radio frequency chip.
3. The radio frequency device of
4. The radio frequency device of
6. The radio frequency device of
9. The radio frequency device of
10. The radio frequency device of
12. The radio frequency device of
13. The radio frequency device of
15. The radio frequency device of
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This application claims priority to U.S. Provisional Patent Application Ser. No. 60/428,257 filed Nov. 22, 2002. The entirety of that provisional application is incorporated herein by reference.
The application incorporates by reference: U.S. patent application Ser. No. 10/636,732, filed Aug. 8, 2003; U.S. patent application Ser. No. 10/615,026, filed Jul. 9, 2003; U.S. patent application Ser. No. 10/118,092, filed Apr. 9, 2002 now U.S. Pat. No. 7,034,688; PCT Patent Application PCT/IB02/01439, filed Apr. 30, 2002; German Patent Application No. 10121126.0, filed Apr. 30, 2001; Mexican Patent Applications No. 010967, filed Oct. 26, 2001, No. 010968, filed Oct. 26, 2001, No. 010969, filed Oct. 26, 2001, No. 010971, filed Oct. 26, 2001, No. 003141, filed Mar. 25, 2002, and No. 003202, filed Mar. 26, 2002.
The present invention relates generally to a system and method for providing secure identification solutions, and specifically to a system and method for providing secure identification solutions utilizing devices with radio frequency (RF) transponders.
The present invention provides systems and methods for transmitting and receiving information from a radio frequency (RF) device (e.g., an RF transponder). A conductive adhesive connects an antenna in a non-metallized region to a metallized region. This feature transforms the entire metallized region of the RF device (i.e., the remainder of the metallized material outside the non-metallized region) into an antenna. This enables greater reading distance and greater data capacity.
In one embodiment, the non-metallized region is a formerly metallized region that has been demetallized. A metal foil substrate which remains following the demetallization process is converted into an antennal surface. This antennal surface captures power as a parabolic or increased area, rather than allowing the metal foil substrate to interfere.
Connection of the antenna to the metallized region can take place in a variety of areas. The following description sets forth two possible attachment configurations (e.g., connections on the sides, connections on the top and bottom), but those experienced in the art will see that multiple other attachment configurations are possible.
The present invention utilizes the following features: passive transponder systems; and retro-reflective, holographic, and other metallic materials.
Passive Transponder Systems. Passive transponder systems are used worldwide for many identification purposes. A passive transponder system is powered by an electromagnetic field of a reader. (No power supply is within the transponder.) A transponder is a transceiver (e.g., a transmitter/receiver that both transmits and receives signals) in a communication satellite that receives a signal from an earth station and retransmits it on a different frequency to one or more other earth stations. An internal antenna of the transponder is used for both data transmission and energy transmission between the reader and the transponder, using, for example, the same frequency for the data and energy transmissions.
Retro-Reflective, Holographic, and Other Metallic Materials. Retro-reflective materials can reflect and re-emit incident light in a direction that is parallel to that of the source of the incident light. In other words, retro-reflective materials reflect light directly back toward the source of the light. Such materials and devices are widely used in the areas of nighttime transportation and safety. For example, retro-reflective materials are used to illuminate highway lanes and road signs using the light emitted from vehicle headlights. Retro-reflective materials are also used for the production of plates and decals for vehicles and for truck containers, tractors and other applications. Retro-reflective materials have a bright effect under direct light without disturbing human sight.
Holographic materials have also been used for identification purposes. Since holograms are difficult to counterfeit, they are increasingly used for identification purposes (e.g., driver's licenses, credit cards, bus passes, etc.) to increase security.
Both retro-reflective and holographic materials typically contain a very high level of metal such as aluminum. Holograms, for example, are typically stamped from metal foils. It is known that metal blocks the transmission and reception of RF signals because the RF signal is absorbed or distorted by the metal content in the material. As a result, the signal cannot be received by an antenna blocked by metal. Such a blocked signal cannot be used, for example, to activate a connected device. This same blocking effect can occur whether the device is positioned on top of or underneath the metallic material because the distortion and absorption of the RF signal will be affected in either case.
The RF Device
In one embodiment of the invention, as described further, for example, in U.S. Provisional Patent Application Ser. No. 60/394,241, filed Jul. 9, 2002, and the corresponding utility U.S. patent application Ser. No. 10/615,026, filed Jul. 9, 2003, a system for delivering security solutions is provided that includes one or more of the following: a radio frequency (RF) device; and an identification mechanism (e.g., a card, sticker, device). According to another embodiment of the present invention, as described further in these applications, the RF device includes retro-reflective, holographic, or other material containing metal, and an antenna for receiving radio frequency (RF) signals.
As explained above, in one embodiment of the present invention, an entire metallized region of an RF device is transformed into an antenna by connecting an antenna in a non-metallized region to a metallized region, allowing for greater reading distance and greater data accuracy. Connecting the antenna in the non-metallized region to the metallized region also aids in overcoming transmission problems created by metallic materials.
The metallized region 110 comprises, for example, the following materials: Retro-Reflective, Holographic, and metallized covers. The non-metallized region 115 comprises, for example, the following materials: PET, PVC, Polypropylene, vinyl. The antenna 120 comprises, for example, the following materials: conductive inks, aluminum, etc. The chip 125 (e.g., Picorypt made by Inside Technologies, Sahara made by BNC US Holding, San Diego, Calif., or any RF chip) comprises control logic for controlling the RF signal and for Analog to Digital or Digital to Analog conversion. The connection 130 comprises, for example, the following materials: gold and/or silver bumps. The holographic image comprises, for example, the following materials: Aluminum. The base layer comprises, for example, the following materials: PET, PVC, Polypropylene, vinyl. The connection 130 connects the sides of the antenna 120 in the non-metallized region 115 to the metallized region 110. The antenna 120 is thus in electrical communication (i.e., electronically coupled) with the chip 125. In one embodiment of the present invention, the non-metallized region 115 has been selectively demetallized such that the chip 125 can transmit and receive information.
Method of Making the RF Device
When the object beam reflects off the subject, it carries with it information about the location, size, shape and texture of the subject. Some of this reflected object beam then meets the reference beam at the holographic film, producing an interference pattern which is recorded in the light sensitive emulsion.
Embossed holograms are holograms with a mirror backing. Embossing is the most frequently used method of mass-production in holography. The holographic information is transferred from light sensitive glass plates to nickel embossing shims. The holographic images are “printed” by stamping the interference pattern onto plastic and then backing the images with a light reflecting foil. The resulting hologram can be duplicated millions of times. In step 315, an antenna is formed on the base layer. In step 320, an RF chip is mounted on the base layer in electrical communication with the antenna to form an RF transponder. In step 325, the antenna in the non-metallized region is connected to the metallized region with a connector (e.g., a conductive adhesive).
Example use of the RF Device
The present invention is described in terms of the above embodiments. This is for convenience only and is not intended to limit the application of the present invention. In fact, after reading the description of the present invention or upon learning by practice of the invention, additional advantages, features, and embodiments of the invention will be apparent to one skilled in the relevant arts.
In addition, it should be understood that the Figures described above, which highlight the functionality and advantages of the present invention, are presented for example purposes only. The architecture of the present invention is sufficiently flexible and configurable, such that it may be utilized in ways other than that shown in the Figures.
Martinez de Velasco Cortina, Francisco
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Mar 30 2005 | BNC, IP SWITZERLAND GMBH | NEOLOGY, INC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 027309 | /0012 | |
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