Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. A security device is placed on the center pin of an open mold before the optical disk is formed. Alternatively, an optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. As a further alternative, two optical platters, each having a complementary cavity to accommodate a security device are created using a special mold having a raised platform. The security device is inserted into the complementary cavities and the optical platters and security device are bonded together.

Abstract: A system and method for securely delivering installation keys from a key generator to an individualization device at a production facility is presented. Operators, using a production key server at the manufacturing facility, send a request to a key release server for a number of installation keys according to a production run. The key release server verifies the request, and if valid, returns the requested number of installation keys to the production key server in an encrypted format. The production key server then decrypts and delivers installation keys to the individualization device in a just-in-time fashion. The production key server includes various security devices including a hardware decryption device to decrypt the installation keys, a smart card reader for authenticating authorized operators, and a limiting switch to disable the production key server if it is tampered with.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. A security device is placed on the center pin of an open mold before the optical disk is formed. Alternatively, an optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. As a further alternative, two optical platters, each having a complementary cavity to accommodate a security device are created using a special mold having a raised platform. The security device is inserted into the complementary cavities and the optical platters and security device are bonded together.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. A security device is placed on the center pin of an open mold before the optical disk is formed. Alternatively, an optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. As a further alternative, two optical platters, each having a complementary cavity to accommodate a security device are created using a special mold having a raised platform. The security device is inserted into the complementary cavities and the optical platters and security device are bonded together.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. An optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. The security device is located in the cavity of the optical disk and bonded to the optical disk.

Abstract: An optical disk comprises a disk substrate having a hub and an annular optical metallicized data region extending radially outward from the hub. The optical disk further comprises a radio frequency identification (RFID) transponder affixed to the disk substrate, e.g., within the non-data containing hub region. The optical disk further comprises at least one linear antenna element coupled to the transponder, e.g., via pole lead(s), and extending within the data region. The antenna element(s) can be applied to the disk substrate as a patterned antenna layer over a metallicized data region, and can be electrically isolated from the data region. A method and system of identifying an optical disk is provided. A radio frequency (RF) signal can be transmitted to the optical disk at a range of at least five feet, and preferably at a range of at least ten feet. An RF signal with an identification code (e.g., a unique number) can be received from the optical disk in response to the transmitted RF signal.

Abstract: A counterfeit-resistant portable storage medium is presented. The counterfeit-resistant portable storage medium comprises a non-volatile solid-state memory for storing data on the storage medium. The counterfeit-resistant portable storage medium also comprises a computer-readable read-only security device storing a security value uniquely identifying the storage medium. A method for delivering counterfeit-resistant data is also presented. The method comprises providing a portable storage medium storing computer-readable data, wherein the portable storage medium comprises a non-volatile memory storing the computer-readable data. The portable storage medium also comprises a computer-readable read-only security device storing a security value that uniquely identifies the portable storage medium.

Abstract: A system and method for writing and extracting tamper resistant security data onto optical media such as for example CDs and DVDs. A unique digital identifier may be embedded onto the lead-in area and/or lead-out area of an optical media, which areas are inaccessible in conventional optical media readers. The digital identifier includes data which, when read, may be used to validate the authenticity of the media, including for example a unique digitally signed serial number for the media, the time and date the media was fabricated and a location where the media was fabricated.

Abstract: A system of visual authentication of digital media. A visual means is provided at the point of purchase for a user to verify that the source of software is genuine. An authentication image is embedded into a portion of a media. The authentication image is not visible to the naked eye. Embodiments of the invention further include a view port integrated in the packaging for the media. The viewing port includes a decoder lens that allows the user to see the hidden authentication image, marking the authenticity of the media.

Abstract: Authenticating the source of digital media is performed by using unique, randomly generated variably encoded frequency patterns to create mastering specific, profiles for sets end user media which can be verified by a manufacturer. A method for verifying the authenticity of an optical storage device includes the steps of: reading a randomly generated signature key value for the optical storage device; determining manufacturing information for the optical storage device; and matching read randomly generated signature key values and manufacturing information with known valid key the to determine the authenticity of the device.

Abstract: Software piracy is inhibited by distributing unique software product keys operable in hardware or a hardware linked device. Software operable on the hardware requires the presence of the key in or accessible via the hardware, and operates only if the hardware product key is present. A method for securing software includes the steps of: providing a plurality of unique product activation keys designed for access by a computer program and delivering the keys to a hardware manufacturer. The computer program seeks at least one of said plurality of unique product activation keys in the read only memory device.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. A security device is placed on the center pin of an open mold before the optical disk is formed. Alternatively, an optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. As a further alternative, two optical platters, each having a complementary cavity to accommodate a security device are created using a special mold having a raised platform. The security device is inserted into the complementary cavities and the optical platters and security device are bonded together.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. An optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. The security device is located in the cavity of the optical disk and bonded to the optical disk.

Abstract: An optical disk comprises a disk substrate having a hub and an annular optical metallicized data region extending radially outward from the hub. The optical disk further comprises a radio frequency identification (RFID) transponder affixed to the disk substrate, e.g., within the non-data containing hub region. The optical disk further comprises at least one linear antenna element coupled to the transponder, e.g., via pole lead(s), and extending within the data region. The antenna element(s) can be applied to the disk substrate as a patterned antenna layer over a metallicized data region, and can be electrically isolated from the data region. A method and system of identifying an optical disk is provided. A radio frequency (RF) signal can be transmitted to the optical disk at a range of at least five feet, and preferably at a range of at least ten feet. An RF signal with an identification code (e.g., a unique number) can be received from the optical disk in response to the transmitted RF signal.

Abstract: Methods for creating optical disks embedded with security devices are presented. A first optical platter and a second optical platter are obtained. The first optical platter has a cavity formed on a surface. A security device is placed between the first and second optical platters such that the security device is located in the cavity of the first optical platter. The first optical platter is bonded to the second optical platter such that the security device is bonded between the first optical platter and the second optical platter to form the counterfeit-resistant optical disk.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. A security device is placed on the center pin of an open mold before the optical disk is formed. Alternatively, an optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. As a further alternative, two optical platters, each having a complementary cavity to accommodate a security device are created using a special mold having a raised platform. The security device is inserted into the complementary cavities and the optical platters and security device are bonded together.

Abstract: A system and method for securely delivering installation keys from a key generator to an individualization device at a production facility is presented. Operators, using a production key server at the manufacturing facility, send a request to a key release server for a number of installation keys according to a production run. The key release server verifies the request, and if valid, returns the requested number of installation keys to the production key server in an encrypted format. The production key server then decrypts and delivers installation keys to the individualization device in a just-in-time fashion. The production key server includes various security devices including a hardware decryption device to decrypt the installation keys, a smart card reader for authenticating authorized operators, and a limiting switch to disable the production key server if it is tampered with.

Abstract: A system and method for installing content on a target computer using individualized installation media is provided. A computer-readable, strong installation key is delivered on the installation media. If the installation key is valid, a timed installation is created and an authentication request is made to an authentication server. If the authentication server determines that the timed installation is authorized, the server responds with an authentication response that is used by the target computer to convert the timed installation into a perpetual installation. The strong installation key may be delivered on various embodiments of installation media, including: a writable media and a read-only media, a hybrid disk, a double-sided DVD disk having a writable platter and a read-only platter, a read-only optical disk where the installation key is determined according to read errors in a reserved area, and an installation media including an RF identification tag.

Abstract: According to the present invention, a plurality of content installations represented by installation images are stored on a single set of installation media. The set of installation media is comprised of at least one data bearing device. Also written to the installation media is at least one installation key, in a computer-readable format. The at least one installation key corresponds to at least one of the plurality of installation images. The installation key is used by an installation process to install at least one of the plurality of installation images onto a target computer.

Abstract: An optical disk with an embedded security device, or wafer, is presented. The security device includes security features that enable the identification of genuine optical disks versus counterfeit optical disks. Methods for creating optical disks embedded with security devices are also presented. A security device is placed on the center pin of an open mold before the optical disk is formed. Alternatively, an optical disk having a cavity formed on a surface to receive a security device is created. A special mold with a raised platform creates the cavity on the optical disk. As a further alternative, two optical platters, each having a complementary cavity to accommodate a security device are created using a special mold having a raised platform. The security device is inserted into the complementary cavities and the optical platters and security device are bonded together.