USRE47246E1 - Integrated circuit for digital rights management - Google Patents

Integrated circuit for digital rights management Download PDF

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USRE47246E1
USRE47246E1 US12/428,206 US42820609A USRE47246E US RE47246 E1 USRE47246 E1 US RE47246E1 US 42820609 A US42820609 A US 42820609A US RE47246 E USRE47246 E US RE47246E
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digital data
integrated circuit
encrypted
flash memory
data
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Dani Dariel
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Western Digital Israel Ltd
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SanDisk IL Ltd
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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F21/00Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
    • G06F21/70Protecting specific internal or peripheral components, in which the protection of a component leads to protection of the entire computer
    • G06F21/71Protecting specific internal or peripheral components, in which the protection of a component leads to protection of the entire computer to assure secure computing or processing of information
    • G06F21/72Protecting specific internal or peripheral components, in which the protection of a component leads to protection of the entire computer to assure secure computing or processing of information in cryptographic circuits
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F21/00Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
    • G06F21/70Protecting specific internal or peripheral components, in which the protection of a component leads to protection of the entire computer
    • G06F21/86Secure or tamper-resistant housings
    • G06F21/87Secure or tamper-resistant housings by means of encapsulation, e.g. for integrated circuits

Definitions

  • the present invention relates to application-specific integrated circuits (ASICs) and, more particularly, to an ASIC that facilitates digital rights management for copyrighted material.
  • ASICs application-specific integrated circuits
  • DRM digital rights management
  • the term “digital rights management” (DRM) encompasses, generally, the secure distribution, promotion and sale of proprietary data such as, but not limited to, audio and video digital content. DRM imposes certain responsibilities on the content owner and on the content consumer. The content owner must create the digital work, protect the digital work by encrypting it, and distribute the encrypted digital work. The consumer downloads the encrypted digital work to his/her platform and pays for a license to decrypt and use the encrypted digital work.
  • DRM digital music player
  • a remote platform such as a mobile telephone, a personal computer, a set-top box or an audio player
  • FIG. 1 is a high-level partial schematic illustration of a DRM system that includes a server 48 for storing and dispensing encrypted digital audio or video data and a remote platform 10 .
  • server 48 is located at a base station 46 of a cellular telephony network and remote platform 10 is a mobile telephone that includes a transceiver 12 and an antenna 14 for communicating with base station 46 .
  • the overall operation of mobile telephone 10 is controlled by a microprocessor-based controller 16 in conjunction with a hardware-protected cryptographic coprocessor 18 .
  • Controller 16 typically includes two microprocessors: one microprocessor for controlling transceiver 12 and the other microprocessor for controlling the other components of mobile telephone 10 .
  • Cryptographic coprocessor 18 is represented in FIG. 1 as a subscriber identity module (SIM) such as is used in mobile telephony systems under the GSM standard.
  • SIM subscriber identity module
  • controller 16 uses transceiver 12 and antenna 14 to transmit encrypted digital audio or video data.
  • server 48 transmits the encrypted digital audio data back to mobile telephone 10 .
  • Controller 16 uses antenna 14 and transceiver 12 to receive the encrypted digital data, and then stores the encrypted digital data in a non-volatile memory 22 that could be, for example, a magnetic hard disk, a flash memory or an EEPROM.
  • non-volatile memory 22 could be an on-board chip, or alternatively a removable device such as a MMC card or a SD card.
  • controller 16 retrieves the encrypted digital data from memory 22 .
  • the encrypted digital data then are decrypted by SIM 18 , and the decrypted digital data are sent to a player 20 .
  • player 20 could be an MP3 player.
  • Player 20 transforms the decrypted digital audio data to analog signals, optionally amplifies the analog signals, and sends the analog signals to a speaker 24 that transforms the audio signals into audible sound.
  • Components 12 , 16 , 18 , 20 and 22 typically are realized as separate integrated circuits that communicate with each other via one or more common buses 26 .
  • the authentication of remote platform 10 to the base station is effected using an asymmetrical algorithm such as RSA, and the encryption and decryption of the digital audio data is effected using a symmetrical algorithm such as DES.
  • the DES encryption keys that remote platform 10 needs to decrypt the encrypted digital data are encrypted using the asymmetrical algorithm prior to being sent to remote platform 10 by the base station.
  • SIM 18 serves as the hardware-protected DRM coprocessor.
  • SIM 18 authenticates remote platform 10 to the base station via controller 16 and transceiver 12 and decrypts the DES keys.
  • Controller 16 uses the decrypted DES keys to decrypt the encrypted digital data stored in memory 22 and then sends the decrypted digital data to player 20 . All the keys needed to implement the authentication of remote platform 10 and the cryptographic functionality of remote platform 10 are stored in SIM 18 .
  • controller 16 sends the digital data to player 20 in clear format, so that a hacker could copy and duplicate the digital data simply by probing bus 26 .
  • remote platform 10 Two alternate embodiments of remote platform 10 are known, in which a separate cryptographic coprocessor such as SIM 18 is not used to implement any of the cryptographic functionality.
  • a separate cryptographic coprocessor such as SIM 18 is not used to implement any of the cryptographic functionality.
  • controller 16 is the hardware-protected DRM processor, and all the cryptographic functionality is handled by controller 16 .
  • Controller 16 authenticates remote platform 10 to the base station, decrypts the encrypted digital data stored in memory 22 , and sends the decrypted digital data to player 20 . All the keys needed to implement the cryptographic functionality are stored in controller 16 .
  • the main drawback of this alternate embodiment is the same as the main drawback of the embodiment of FIG. 1 : controller 16 sends the digital data to player 20 in clear format, so that a hacker could copy and duplicate the digital audio data simply by probing bus 26 .
  • the cryptographic functionality is distributed between controller 16 and player 20 , so that both controller 16 and player 20 serve as hardware-protected DRM processors.
  • Controller 16 authenticates remote platform 10 to the base station and sends the encrypted digital data to player 20 .
  • Player 20 decrypts the encrypted digital data.
  • the keys needed for authentication are stored in controller 16 .
  • the keys needed for decryption are stored in player 20 .
  • the main drawback of this alternate embodiment is the extra expense of two components with cryptographic capabilities.
  • controller 16 and player 20 of FIG. 1 are pure logic integrated circuits. Controller 16 of the two alternative embodiments, and player 20 of the second alternative embodiment, must also include their own read/write non-volatile memories, so that the secret cryptographic keys can be replaced as necessary. Integrating a non-volatile memory in an otherwise pore logic integrated circuit may raise the cost of the integrated circuit substantially.
  • an integrated circuit including: (a) a processor for: (i) requesting encrypted digital data, and (ii) decrypting the encrypted digital data, thereby providing decrypted digital data; and (b) a player for transforming the decrypted digital data to analog signals.
  • a system for displaying digital data including: (a) a server for storing the digital data in an encrypted form; and (b) a user platform including: (i) an integrated circuit that includes: (A) a processor for: (I) requesting the encrypted digital data from the server, and (II) decrypting the encrypted digital data, thereby providing decrypted digital data, and (B) a player for transforming the decrypted digital data to analog signals.
  • a method of requesting encrypted digital data from a server and then decrypting and displaying the encrypted digital data including the steps of: (a) providing an integrated circuit that includes: (i) a processor operative to: (A) request the encrypted digital data from the server and (B) decrypt the encrypted digital data, thereby providing decrypted digital data, and (ii) a player operative to transform the decrypted digital data to analog signals; (b) requesting the encrypted digital data from the server, by the processor; (c) decrypting the encrypted digital data, by the processor, thereby providing the decrypted digital data; and (d) transforming the decrypted digital data to analog signals, by the player.
  • the integrated circuit of the present invention is an ASIC that implements the cryptographic functionality of prior art controller 16 and SIM 18 but that outputs analog signals directly to speaker 24 .
  • the basic components of the integrated circuit of the present invention are a processor for requesting encrypted digital data from a server and for decrypting the encrypted digital data to provide decrypted digital data, and a player for transforming the decrypted digital data to analog signals.
  • the basic steps of the method of the present invention include the steps of providing the basic integrated circuit of the present invention, using the processor to request the encrypted digital data from the server, using the processor to decrypt the encrypted digital data, and using the player to transform the decrypted digital data to analog signals.
  • “requesting” the encrypted digital data includes authenticating the integrated circuit to the server.
  • the authentication is effected using an asymmetrical algorithm, for example a RSA algorithm or a ECC algorithm.
  • the decrypting of the encrypted digital data is effected using a symmetrical algorithm, for example a DES algorithm or a Rijndael algorithm.
  • the integrated circuit of the present invention is tamper-resistant.
  • the integrated circuit is reset.
  • Particular examples of the kinds of digital data for which the present invention is suitable include digital audio data and digital video data.
  • the interface via which the processor receives the encrypted digital data may be any suitable interface, for example an ISO7816 interface, a local bus interface, a MMCA interface, a SDA interface, a USB interface or a parallel interface.
  • the form factor of the integrated circuit of the present invention may be any suitable form factor, for example a SIM form factor, a TQFP form factor, a DIP form factor, a SOP form factor or a BGA form factor.
  • the integrated circuit of the present invention includes only one processor. Nevertheless, the integrated circuit of the present invention may include, and usually does include, one or more coprocessors.
  • a coprocessor is a state machine that is provided in addition to the processor for performing specialized tasks under the direction of the processor.
  • the integrated circuit of the present invention includes a ROM for storing management code that is executed by the processor to operate the integrated circuit.
  • the management code of the integrated circuit is stored only in the ROM, and not, for example, in a memory such as an EEPROM that can be erased and rewritten electronically.
  • the scope of the present invention also includes a device (also referred to herein as a “user platform”, for receiving, decrypting and displaying encrypted digital data, that includes the integrated circuit of the present invention.
  • the device of the present invention also includes a transceiver for transmitting a request from the processor for the encrypted digital data and for receiving the encrypted digital data.
  • the device of the present invention also includes a display mechanism for displaying the analog signals.
  • displaying means transforming the analog signals into corresponding physical sensations that can be perceived by a user of the device, so that speaker 24 , that transforms incoming analog signals to audible sound, is an example of a “display mechanism” as understood herein, as is a video screen for transforming incoming analog signals to a visible video image.
  • the device of the present invention includes a nonvolatile memory such as a flash memory for storing the encrypted data.
  • the method of the present invention preferably includes the step of storing the encrypted digital data in the nonvolatile memory.
  • the scope of the present invention also includes a DRM system that includes both the device of the present invention and a server, wherein the digital data are stored, that transmits the digital data to the device when a request accompanied by a valid authentication is received from the device by the server.
  • the server is configured to transmit substantially only the encrypted digital data, and the keys needed to decrypt the encrypted digital data, to the device.
  • Decrypting the encrypted digital data typically requires at least one cryptographic key.
  • the method of the present invention preferably includes the steps of having the processor request the key(s) needed for decrypting from the server and then storing the key(s) in the nonvolatile memory. Most preferably, the key(s) is/are encrypted before being stored in the non-volatile memory.
  • Gressel et al. in published US patent application no. 2002/0070272, teach an integrated circuit for authenticating a remote user of a host system to the host system so that the user can download and run programs such as Java scripts from the host system.
  • the problem addressed by Gressel et al. is that if the users use prior art smart cards of the type illustrated in FIG. 3 of Gressel et al. to authenticate themselves to the host system, a malicious system programmer could devise code to hack the smart cards from the host system. Therefore, the functionality of the integrated circuit of Gressel et al. is partitioned between two sections, a “security application module” that handles the cryptographic functionality and a “trusted application computing environment” for executing the programs received from the host system.
  • each section has its own processor.
  • each section also has its own digital-to-analog converter.
  • the intended use of the embodiment of FIG. 9 of Gressel et al. is for combining unenhanced video data from the host with encrypted audio data and encrypted video enhancement data purchased separately by the user, and then displaying the combined data.
  • the present invention is based on the insight that there are environments in which the high degree of security taught by Gressel et al. is not needed.
  • the primary reason for downloading code to a smart card or to a SIM is to upgrade the software of the smart card or the SIM.
  • the operator of a cellular telephone network may choose to secure the subscriber's SIMs 18 against hacking by never downloading executable code from server 48 , but instead upgrading the SIMs 18 by some other means, for example issuing new SIMs to the subscribers.
  • the operator may use some other method, such as third-party byte code certification, to check all code for malicious tampering before downloading the code from server 48 .
  • SIM 18 a prior art smart card such as the smart card of FIG. 3 of Gressel et al., or the equivalent SIM 18 , is perfectly secure. Including a player with a digital-to-analog converter in SIM 18 turns SIM 18 into an integrated circuit, for decrypting and displaying encrypted digital data, that is relatively immune both to physical probing by a local hacker and to remote hacking from server 48 .
  • FIG. 1 is a high-level schematic block diagram of a prior art DRM system
  • FIG. 2 is a high-level schematic block diagram of a DRM system of the present invention.
  • the present invention is of an ASIC for implementing digital rights management and of a DRM system that includes a user platform based on that ASIC. Specifically, the present invention can be used to control distribution of proprietary digital data to remote platforms.
  • FIG. 2 is a high-level partial schematic illustration of a system 60 of the present invention.
  • System 60 includes a server 50 , substituted for server 48 in base station 46 , and a remote platform 28 that, like remote platform 10 , is configured as a mobile telephone, in order to communicate with server 50 in base station 46 .
  • Remote platform 28 is similar to remote platform 10 , but with an ASIC 30 of the present invention, along with a flash memory 38 , substituted for SIM 18 and player 20 .
  • the other components of remote platform 28 are substantially identical to the corresponding components of remote platform 10 , and so are designated in FIG. 2 by the same reference numerals as in FIG. 1 . All of the cryptographic functionality of remote platform 28 is performed by ASIC 30 .
  • ASIC 30 includes the following illustrated components:
  • ASIC 30 also includes several components, such as a power management module, a random number generator, an interrupt controller and an internal clock, that, for illustrational clarity, are not included in FIG. 2 All the components of ASIC 30 are fabricated together on a common substrate as a single integrated circuit.
  • ASIC 30 and flash memory 38 which is itself an ASIC, are packaged together in a common package 44 .
  • Flash memory 38 is used, under the control of flash memory controller 40 , to store and retrieve encrypted digital audio data. As requested by a user of remote platform 28 , the encrypted digital audio data are decrypted and sent to player 34 .
  • Player 34 differs from player 20 in that unlike player 20 , player 34 does no digital processing of its own.
  • Player 34 essentially is just a digital-to-analog converter that transforms the decrypted digital data to analog signals that are transformed to user-perceptible sensations by display mechanism 24 .
  • display mechanism 24 is a speaker that transforms the analog signals to audible sound.
  • ASIC 30 is shown as including one cryptographic coprocessor 34 36.
  • ASIC 30 includes several cryptographic coprocessors 34 36, also called “cores”, each for implementing a respective cryptographic algorithm.
  • ASIC 30 includes four cores 34 36: an AES core, a DES core, a SHA-1 core and a RSA/ECC core.
  • ASIC 30 is shown as including two sensors 42 .
  • ASIC 30 includes a variety of sensors, in its outer layers. These sensors are selected from among voltage sensors, probe sensors, wire sensors, piezoelectric sensors, motion sensors, ultrasonic sensors, microwave sensors, infrared sensors, accelerations sensors, radiation flux sensors, radiation dosage sensors and temperature sensors, as described by S. H. Weingart in “Physical security devices for computer subsystems: a survey of attacks and defenses”, Lecture Notes in Computer Science vol. 1965 pp. 302-317 (2001), which publication is incorporated by reference for all purposes as if fully set forth herein. Detection by one of sensors 42 of an attempt to tamper with ASIC 30 triggers a reset of ASIC 30 to prevent a hacker from reading the cryptographic keys off of bus 58 .
  • the management code of ASIC 30 is fixed in ROM 52 . Upgrading the management code of ASIC 30 is effected by physically replacing the entire ASIC 30 by a new ASIC 30 with an upgraded ROM 52 . It therefore being unnecessary to download management code from server 50 to ASIC 30 , server 50 is configured to send to remote platform 28 essentially only encrypted digital data and keys for decrypting the encrypted digital data.
  • remote platform 28 The operation of remote platform 28 is as follows. Using one or more of the authentication keys stored in EEPROM 56 , processor 32 authenticates remote platform 28 to server 50 at base station 46 , via controller 16 and transceiver 12 , as part of a request for the transmission of encrypted digital audio or video data. The authentication is done using an asymmetrical algorithm such as RSA or ECC. Server 50 sends the requested encrypted digital data from base station 46 to remote platform 28 . Processor 32 receives the requested encrypted digital data via transceiver 12 and controller 16 , and uses flash controller 40 to store the received encrypted digital data in flash memory 38 . Server 50 also sends one or more decryption keys from base station 46 to remote platform 28 .
  • Processor 32 receives the decryption key(s) via transceiver 12 and controller 16 , and then stores the decryption keys in EEPROM 56 .
  • coprocessor 36 encrypts the decryption key(s) and uses flash controller 40 to store the encrypted decryption key(s) in flash memory 38 .
  • the user enters the appropriate command at a user command interface (not shown) of remote platform 28 , instructing processor 32 , via controller 16 , to retrieve and decrypt the encrypted digital data.
  • Processor 32 then uses flash controller 40 to retrieve the encrypted digital data from flash memory 22 and then uses coprocessor 36 and the appropriate decryption keys from EEPROM 56 to decrypt the encrypted digital data.
  • ASIC 30 lacks EEPROM 56 . Instead, a unique key, for example a DES key, that remains the same for the lifetime of ASIC 30 , is stored in ROM 52 . This key is used by processor 32 and coprocessor 36 to encrypt the other keys, which then are stored in encrypted form in flash memory 38 and are retrieved from flash memory 38 and decrypted by processor 32 and coprocessor 36 as needed.
  • a unique key for example a DES key, that remains the same for the lifetime of ASIC 30 , is stored in ROM 52 . This key is used by processor 32 and coprocessor 36 to encrypt the other keys, which then are stored in encrypted form in flash memory 38 and are retrieved from flash memory 38 and decrypted by processor 32 and coprocessor 36 as needed.
  • ASIC 30 is described herein as a replacement for SIM 18 should not be interpreted as requiring that ASIC 30 have a SIM form factor.
  • ASIC 30 may have any suitable form factor, for example a TQFP form factor, a DIP form factor, a SOP form factor or a BGA form factor.
  • the interface between ASIC 30 and bus 26 need not be the ISO7816 interface that is standard for SIMs, but may be any suitable interface, for example a local bus interface, a MMCA interface, a SDA interface, a USB interface or a parallel interface.
  • ASIC 30 that the digital input to ASIC 30 is encrypted, whereas the output from ASIC 30 is analog rather than digital, inhibits unlicensed copying of the data.
  • analog signals emerging from ASIC 30 are in clear format, their quality is sufficiently low, relative to the input digital data, to provide a disincentive to unlicensed copying.
  • Remote platform 28 has only one integrated circuit with cryptographic capabilities, unlike the second alternate prior art embodiment which requires two integrated circuits with cryptographic capabilities.
  • fabrication of ASIC 30 requires the integration of logic circuits and memory circuits in the same integrated circuit, so does the fabrication of SIM 18 .

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Abstract

An ASIC for implementing digital rights management includes a processor for requesting encrypted digital data from a server and decrypting the data, and a player for transforming the decrypted data to analog signals. Preferably, the ASIC is tamper-resistant. Preferably, all the management code of the ASIC is stored on a ROM in the ASIC. A device for receiving, decrypting and displaying encrypted digital data includes the ASIC, and also a transceiver for communicating with the server, a display mechanism for displaying the analog signals, and a nonvolatile memory for storing the encrypted data. A system for storing and displaying digital data includes both the server and the device. Preferably, the server is configured to send to the device only the encrypted digital data and associated decryption keys.

Description

This is an application to Reissue U.S. Pat. No. 7,213,157, issued from U.S. patent application Ser. No. 11/325,314, filed Jan. 5, 2006, which is a Continuation of U.S. patent application Ser. No. 10/634,872 filed Aug. 6, 2003, now U.S. Pat. No. 7,058,818 which is a Continuation-In-Part of U.S. Provisional Application No. 60/401,753, filed Aug. 8, 2002.
FIELD AND BACKGROUND OF THE INVENTION
The present invention relates to application-specific integrated circuits (ASICs) and, more particularly, to an ASIC that facilitates digital rights management for copyrighted material.
The term “digital rights management” (DRM) encompasses, generally, the secure distribution, promotion and sale of proprietary data such as, but not limited to, audio and video digital content. DRM imposes certain responsibilities on the content owner and on the content consumer. The content owner must create the digital work, protect the digital work by encrypting it, and distribute the encrypted digital work. The consumer downloads the encrypted digital work to his/her platform and pays for a license to decrypt and use the encrypted digital work.
Among the ways in which DRM can be implemented on a remote platform such as a mobile telephone, a personal computer, a set-top box or an audio player, are the following:
1. Software protection only: a software module integrated in the operating system of the platform controls authentication and data decryption. The main drawback of this solution is the lack of a secured element to store the secret keys used for authentication and decryption and for performing the authentication and decryption. Another drawback of this solution is that the cryptographic computations are not done in a secure, encapsulated environment. A hacker can copy and duplicate the decrypted data simply by probing the platform bus.
2. Secure system: the entire DRM process is performed by one or more hardware-protected (co)processor(s). This solution provides a higher level of security.
FIG. 1 is a high-level partial schematic illustration of a DRM system that includes a server 48 for storing and dispensing encrypted digital audio or video data and a remote platform 10. In the specific embodiment of a DRM platform that is illustrated in FIG. 1, server 48 is located at a base station 46 of a cellular telephony network and remote platform 10 is a mobile telephone that includes a transceiver 12 and an antenna 14 for communicating with base station 46. The overall operation of mobile telephone 10 is controlled by a microprocessor-based controller 16 in conjunction with a hardware-protected cryptographic coprocessor 18. Controller 16 typically includes two microprocessors: one microprocessor for controlling transceiver 12 and the other microprocessor for controlling the other components of mobile telephone 10. Cryptographic coprocessor 18 is represented in FIG. 1 as a subscriber identity module (SIM) such as is used in mobile telephony systems under the GSM standard. Using transceiver 12 and antenna 14, controller 16 transmits to server 48 at base station 46 a request (including user identification and payment instructions) to download encrypted digital audio or video data. In response, server 48 transmits the encrypted digital audio data back to mobile telephone 10. Controller 16 uses antenna 14 and transceiver 12 to receive the encrypted digital data, and then stores the encrypted digital data in a non-volatile memory 22 that could be, for example, a magnetic hard disk, a flash memory or an EEPROM. With regard to form factor, non-volatile memory 22 could be an on-board chip, or alternatively a removable device such as a MMC card or a SD card. When the user of mobile telephone 10 wishes to play the data, controller 16 retrieves the encrypted digital data from memory 22. The encrypted digital data then are decrypted by SIM 18, and the decrypted digital data are sent to a player 20. For example, if the downloaded data are audio data, player 20 could be an MP3 player. Player 20 then transforms the decrypted digital audio data to analog signals, optionally amplifies the analog signals, and sends the analog signals to a speaker 24 that transforms the audio signals into audible sound.
Components 12, 16, 18, 20 and 22 typically are realized as separate integrated circuits that communicate with each other via one or more common buses 26.
It is commonly recognized that the most secure form of DRM relies on a public key infrastructure. Preferably, the authentication of remote platform 10 to the base station is effected using an asymmetrical algorithm such as RSA, and the encryption and decryption of the digital audio data is effected using a symmetrical algorithm such as DES. The DES encryption keys that remote platform 10 needs to decrypt the encrypted digital data are encrypted using the asymmetrical algorithm prior to being sent to remote platform 10 by the base station.
In the embodiment of remote platform 10 that is illustrated in FIG. 1, SIM 18 serves as the hardware-protected DRM coprocessor. SIM 18 authenticates remote platform 10 to the base station via controller 16 and transceiver 12 and decrypts the DES keys. Controller 16 uses the decrypted DES keys to decrypt the encrypted digital data stored in memory 22 and then sends the decrypted digital data to player 20. All the keys needed to implement the authentication of remote platform 10 and the cryptographic functionality of remote platform 10 are stored in SIM 18. The main drawback of this embodiment is that controller 16 sends the digital data to player 20 in clear format, so that a hacker could copy and duplicate the digital data simply by probing bus 26.
Two alternate embodiments of remote platform 10 are known, in which a separate cryptographic coprocessor such as SIM 18 is not used to implement any of the cryptographic functionality.
In the first alternate embodiment of remote platform 10, controller 16 is the hardware-protected DRM processor, and all the cryptographic functionality is handled by controller 16. Controller 16 authenticates remote platform 10 to the base station, decrypts the encrypted digital data stored in memory 22, and sends the decrypted digital data to player 20. All the keys needed to implement the cryptographic functionality are stored in controller 16. The main drawback of this alternate embodiment is the same as the main drawback of the embodiment of FIG. 1: controller 16 sends the digital data to player 20 in clear format, so that a hacker could copy and duplicate the digital audio data simply by probing bus 26.
In the second alternate embodiment of remote platform 10, the cryptographic functionality is distributed between controller 16 and player 20, so that both controller 16 and player 20 serve as hardware-protected DRM processors. Controller 16 authenticates remote platform 10 to the base station and sends the encrypted digital data to player 20. Player 20 decrypts the encrypted digital data. The keys needed for authentication are stored in controller 16. The keys needed for decryption are stored in player 20. The main drawback of this alternate embodiment is the extra expense of two components with cryptographic capabilities.
An additional drawback of the two alternative embodiments, as compared to the embodiment of FIG. 1, is that controller 16 and player 20 of FIG. 1 are pure logic integrated circuits. Controller 16 of the two alternative embodiments, and player 20 of the second alternative embodiment, must also include their own read/write non-volatile memories, so that the secret cryptographic keys can be replaced as necessary. Integrating a non-volatile memory in an otherwise pore logic integrated circuit may raise the cost of the integrated circuit substantially.
There is thus a widely recognized need for, and it would be highly advantageous to have, a hardware-protected DRM ASIC for remote platforms that would overcome the disadvantages of presently known systems as described above.
SUMMARY OF THE INVENTION
According to the present invention there is provided an integrated circuit including: (a) a processor for: (i) requesting encrypted digital data, and (ii) decrypting the encrypted digital data, thereby providing decrypted digital data; and (b) a player for transforming the decrypted digital data to analog signals.
According to the present invention there is provided a system for displaying digital data, including: (a) a server for storing the digital data in an encrypted form; and (b) a user platform including: (i) an integrated circuit that includes: (A) a processor for: (I) requesting the encrypted digital data from the server, and (II) decrypting the encrypted digital data, thereby providing decrypted digital data, and (B) a player for transforming the decrypted digital data to analog signals.
According to the present invention there is provided a method of requesting encrypted digital data from a server and then decrypting and displaying the encrypted digital data, including the steps of: (a) providing an integrated circuit that includes: (i) a processor operative to: (A) request the encrypted digital data from the server and (B) decrypt the encrypted digital data, thereby providing decrypted digital data, and (ii) a player operative to transform the decrypted digital data to analog signals; (b) requesting the encrypted digital data from the server, by the processor; (c) decrypting the encrypted digital data, by the processor, thereby providing the decrypted digital data; and (d) transforming the decrypted digital data to analog signals, by the player.
Essentially, the integrated circuit of the present invention is an ASIC that implements the cryptographic functionality of prior art controller 16 and SIM 18 but that outputs analog signals directly to speaker 24. The basic components of the integrated circuit of the present invention are a processor for requesting encrypted digital data from a server and for decrypting the encrypted digital data to provide decrypted digital data, and a player for transforming the decrypted digital data to analog signals. Correspondingly, the basic steps of the method of the present invention include the steps of providing the basic integrated circuit of the present invention, using the processor to request the encrypted digital data from the server, using the processor to decrypt the encrypted digital data, and using the player to transform the decrypted digital data to analog signals.
Preferably, “requesting” the encrypted digital data includes authenticating the integrated circuit to the server. Most preferably, the authentication is effected using an asymmetrical algorithm, for example a RSA algorithm or a ECC algorithm.
Preferably, the decrypting of the encrypted digital data is effected using a symmetrical algorithm, for example a DES algorithm or a Rijndael algorithm.
Preferably, the integrated circuit of the present invention is tamper-resistant. When an attempt to tamper with the integrated circuit is detected, the integrated circuit is reset.
Particular examples of the kinds of digital data for which the present invention is suitable include digital audio data and digital video data.
The interface via which the processor receives the encrypted digital data may be any suitable interface, for example an ISO7816 interface, a local bus interface, a MMCA interface, a SDA interface, a USB interface or a parallel interface.
The form factor of the integrated circuit of the present invention may be any suitable form factor, for example a SIM form factor, a TQFP form factor, a DIP form factor, a SOP form factor or a BGA form factor.
Preferably, the integrated circuit of the present invention includes only one processor. Nevertheless, the integrated circuit of the present invention may include, and usually does include, one or more coprocessors. A coprocessor is a state machine that is provided in addition to the processor for performing specialized tasks under the direction of the processor.
Preferably, the integrated circuit of the present invention includes a ROM for storing management code that is executed by the processor to operate the integrated circuit. Most preferably, the management code of the integrated circuit is stored only in the ROM, and not, for example, in a memory such as an EEPROM that can be erased and rewritten electronically.
The scope of the present invention also includes a device (also referred to herein as a “user platform”, for receiving, decrypting and displaying encrypted digital data, that includes the integrated circuit of the present invention. Preferably, the device of the present invention also includes a transceiver for transmitting a request from the processor for the encrypted digital data and for receiving the encrypted digital data. Preferably, the device of the present invention also includes a display mechanism for displaying the analog signals. Note that the term “displaying”, as used herein, means transforming the analog signals into corresponding physical sensations that can be perceived by a user of the device, so that speaker 24, that transforms incoming analog signals to audible sound, is an example of a “display mechanism” as understood herein, as is a video screen for transforming incoming analog signals to a visible video image.
Preferably, the device of the present invention includes a nonvolatile memory such as a flash memory for storing the encrypted data. Correspondingly, the method of the present invention preferably includes the step of storing the encrypted digital data in the nonvolatile memory.
The scope of the present invention also includes a DRM system that includes both the device of the present invention and a server, wherein the digital data are stored, that transmits the digital data to the device when a request accompanied by a valid authentication is received from the device by the server. Preferably, the server is configured to transmit substantially only the encrypted digital data, and the keys needed to decrypt the encrypted digital data, to the device.
Decrypting the encrypted digital data typically requires at least one cryptographic key. The method of the present invention preferably includes the steps of having the processor request the key(s) needed for decrypting from the server and then storing the key(s) in the nonvolatile memory. Most preferably, the key(s) is/are encrypted before being stored in the non-volatile memory.
Gressel et al., in published US patent application no. 2002/0070272, teach an integrated circuit for authenticating a remote user of a host system to the host system so that the user can download and run programs such as Java scripts from the host system. The problem addressed by Gressel et al. is that if the users use prior art smart cards of the type illustrated in FIG. 3 of Gressel et al. to authenticate themselves to the host system, a malicious system programmer could devise code to hack the smart cards from the host system. Therefore, the functionality of the integrated circuit of Gressel et al. is partitioned between two sections, a “security application module” that handles the cryptographic functionality and a “trusted application computing environment” for executing the programs received from the host system. The functionality is partitioned in a way that prevents hacking of the security application module from the host system. Each section has its own processor. In the embodiment illustrated in FIG. 9 of Gressel et al., each section also has its own digital-to-analog converter. The intended use of the embodiment of FIG. 9 of Gressel et al. is for combining unenhanced video data from the host with encrypted audio data and encrypted video enhancement data purchased separately by the user, and then displaying the combined data.
In part, the present invention is based on the insight that there are environments in which the high degree of security taught by Gressel et al. is not needed. Generally, the primary reason for downloading code to a smart card or to a SIM is to upgrade the software of the smart card or the SIM. In the context of cellular telephony, for example, the operator of a cellular telephone network may choose to secure the subscriber's SIMs 18 against hacking by never downloading executable code from server 48, but instead upgrading the SIMs 18 by some other means, for example issuing new SIMs to the subscribers. Alternatively, the operator may use some other method, such as third-party byte code certification, to check all code for malicious tampering before downloading the code from server 48. Under such circumstances, a prior art smart card such as the smart card of FIG. 3 of Gressel et al., or the equivalent SIM 18, is perfectly secure. Including a player with a digital-to-analog converter in SIM 18 turns SIM 18 into an integrated circuit, for decrypting and displaying encrypted digital data, that is relatively immune both to physical probing by a local hacker and to remote hacking from server 48.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention is herein described, by way of example only, with reference to the accompanying drawings, wherein:
FIG. 1 is a high-level schematic block diagram of a prior art DRM system;
FIG. 2 is a high-level schematic block diagram of a DRM system of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The present invention is of an ASIC for implementing digital rights management and of a DRM system that includes a user platform based on that ASIC. Specifically, the present invention can be used to control distribution of proprietary digital data to remote platforms.
The principles and operation of an ASIC according to the present invention may be better understood with reference to the drawings and the accompanying description.
Returning now to the drawings, FIG. 2 is a high-level partial schematic illustration of a system 60 of the present invention. System 60 includes a server 50, substituted for server 48 in base station 46, and a remote platform 28 that, like remote platform 10, is configured as a mobile telephone, in order to communicate with server 50 in base station 46. Remote platform 28 is similar to remote platform 10, but with an ASIC 30 of the present invention, along with a flash memory 38, substituted for SIM 18 and player 20. The other components of remote platform 28 are substantially identical to the corresponding components of remote platform 10, and so are designated in FIG. 2 by the same reference numerals as in FIG. 1. All of the cryptographic functionality of remote platform 28 is performed by ASIC 30.
ASIC 30 includes the following illustrated components:
    • A processor 32 for overall management of ASIC 30.
    • A dedicated cryptographic coprocessor 36 for cryptographic functionality.
    • An ASIC ROM 52 for storing the management code of ASIC 30.
    • An ASIC RAM 54 that is used by processor 32 for temporary storage.
    • A flash memory controller 40 for controlling flash memory 38.
    • A player 34.
    • An ASIC EEPROM 56 for storing the cryptographic keys.
    • Several sensors 42 for detecting attempts to physically tamper with ASIC 30.
    • An ASIC bus 58 via which the other components of ASIC 30 communicate with each other.
ASIC 30 also includes several components, such as a power management module, a random number generator, an interrupt controller and an internal clock, that, for illustrational clarity, are not included in FIG. 2 All the components of ASIC 30 are fabricated together on a common substrate as a single integrated circuit.
ASIC 30 and flash memory 38, which is itself an ASIC, are packaged together in a common package 44. Flash memory 38 is used, under the control of flash memory controller 40, to store and retrieve encrypted digital audio data. As requested by a user of remote platform 28, the encrypted digital audio data are decrypted and sent to player 34.
Player 34 differs from player 20 in that unlike player 20, player 34 does no digital processing of its own. Player 34 essentially is just a digital-to-analog converter that transforms the decrypted digital data to analog signals that are transformed to user-perceptible sensations by display mechanism 24. For example, if the digital data are audio data, then display mechanism 24 is a speaker that transforms the analog signals to audible sound.
For illustrational simplicity, ASIC 30 is shown as including one cryptographic coprocessor 34 36. Typically, ASIC 30 includes several cryptographic coprocessors 34 36, also called “cores”, each for implementing a respective cryptographic algorithm. For example, one embodiment of ASIC 30 includes four cores 34 36: an AES core, a DES core, a SHA-1 core and a RSA/ECC core.
Also for illustrational simplicity, ASIC 30 is shown as including two sensors 42. Typically, ASIC 30 includes a variety of sensors, in its outer layers. These sensors are selected from among voltage sensors, probe sensors, wire sensors, piezoelectric sensors, motion sensors, ultrasonic sensors, microwave sensors, infrared sensors, accelerations sensors, radiation flux sensors, radiation dosage sensors and temperature sensors, as described by S. H. Weingart in “Physical security devices for computer subsystems: a survey of attacks and defenses”, Lecture Notes in Computer Science vol. 1965 pp. 302-317 (2001), which publication is incorporated by reference for all purposes as if fully set forth herein. Detection by one of sensors 42 of an attempt to tamper with ASIC 30 triggers a reset of ASIC 30 to prevent a hacker from reading the cryptographic keys off of bus 58.
In this particular preferred embodiment of the present invention, the management code of ASIC 30 is fixed in ROM 52. Upgrading the management code of ASIC 30 is effected by physically replacing the entire ASIC 30 by a new ASIC 30 with an upgraded ROM 52. It therefore being unnecessary to download management code from server 50 to ASIC 30, server 50 is configured to send to remote platform 28 essentially only encrypted digital data and keys for decrypting the encrypted digital data.
The operation of remote platform 28 is as follows. Using one or more of the authentication keys stored in EEPROM 56, processor 32 authenticates remote platform 28 to server 50 at base station 46, via controller 16 and transceiver 12, as part of a request for the transmission of encrypted digital audio or video data. The authentication is done using an asymmetrical algorithm such as RSA or ECC. Server 50 sends the requested encrypted digital data from base station 46 to remote platform 28. Processor 32 receives the requested encrypted digital data via transceiver 12 and controller 16, and uses flash controller 40 to store the received encrypted digital data in flash memory 38. Server 50 also sends one or more decryption keys from base station 46 to remote platform 28. Processor 32 receives the decryption key(s) via transceiver 12 and controller 16, and then stores the decryption keys in EEPROM 56. (Alternatively, coprocessor 36 encrypts the decryption key(s) and uses flash controller 40 to store the encrypted decryption key(s) in flash memory 38.) When a user wishes to play the data, the user enters the appropriate command at a user command interface (not shown) of remote platform 28, instructing processor 32, via controller 16, to retrieve and decrypt the encrypted digital data. Processor 32 then uses flash controller 40 to retrieve the encrypted digital data from flash memory 22 and then uses coprocessor 36 and the appropriate decryption keys from EEPROM 56 to decrypt the encrypted digital data. The decryption is done using a symmetrical algorithm such as DES or Rijndael. Processor 32 then decodes the resulting decrypted digital data and sends the decoded data to player 34, which transforms the decoded data to analog signals and sends the analog signals to display mechanism 24. An alternative embodiment of ASIC 30 lacks EEPROM 56. Instead, a unique key, for example a DES key, that remains the same for the lifetime of ASIC 30, is stored in ROM 52. This key is used by processor 32 and coprocessor 36 to encrypt the other keys, which then are stored in encrypted form in flash memory 38 and are retrieved from flash memory 38 and decrypted by processor 32 and coprocessor 36 as needed.
That ASIC 30 is described herein as a replacement for SIM 18 should not be interpreted as requiring that ASIC 30 have a SIM form factor. ASIC 30 may have any suitable form factor, for example a TQFP form factor, a DIP form factor, a SOP form factor or a BGA form factor. Similarly, the interface between ASIC 30 and bus 26 need not be the ISO7816 interface that is standard for SIMs, but may be any suitable interface, for example a local bus interface, a MMCA interface, a SDA interface, a USB interface or a parallel interface.
That the digital input to ASIC 30 is encrypted, whereas the output from ASIC 30 is analog rather than digital, inhibits unlicensed copying of the data. Although the analog signals emerging from ASIC 30 are in clear format, their quality is sufficiently low, relative to the input digital data, to provide a disincentive to unlicensed copying.
Furthermore, unlike the alternate prior art embodiments discussed above, there are no significant incremental costs associated with the substitution of ASIC 30 for SIM 18 and player 20. Remote platform 28 has only one integrated circuit with cryptographic capabilities, unlike the second alternate prior art embodiment which requires two integrated circuits with cryptographic capabilities. Furthermore, although the fabrication of ASIC 30 requires the integration of logic circuits and memory circuits in the same integrated circuit, so does the fabrication of SIM 18.
While the invention has been described with respect to a limited number of embodiments, it will be appreciated that many variations, modifications and other applications of the invention may be made.

Claims (117)

What is claimed is:
1. A device for digital rights management, comprising:
(a) an integrated circuit including:
(i) a processor for:
(A) requesting encrypted digital data, and
(B) decrypting said encrypted digital data, thereby providing decrypted digital data; and
(ii) a player for transforming said decrypted digital data to analog signals; and
(b) a flash memory for storing said encrypted digital data;
wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
2. The device of claim 1, wherein said encrypted digital data are requested from a server and wherein said requesting of said encrypted digital data includes authenticating said integrated circuit to said server.
3. The device of claim 1, wherein said integrated circuit is tamper-resistant.
4. The device of claim 1, wherein said encrypted digital data are audio data.
5. The device of claim 1, wherein said encrypted digital data are video data.
6. The device of claim 1, wherein said processor includes an interface for receiving said encrypted digital data.
7. The device of claim 6, wherein said interface is selected from the group consisting of an ISO7816 interface, a local bus interface, a MMCA interface, a SDA interface, a USB interface and a parallel interface.
8. The device of claim 1, wherein said integrated circuit has a form factor selected from the group consisting of a SIM form factor, a TQFP form factor, a DIP form factor, a SOP form factor and a BGA form factor.
9. The device of claim 1, further comprising:
(c) a transceiver for transmitting a request for said encrypted digital data from said processor and for receiving said encrypted digital data.
10. The device of claim 1, further comprising:
(c) a display mechanism for displaying said analog signals.
11. The device of claim 1, wherein said integrated circuit includes a single said processor.
12. The device of claim 1, wherein said integrated circuit further includes:
(iii) a ROM for storing management code that is executed by said processor to operate said integrated circuit.
13. The device of claim 12, wherein said management code is stored only in said ROM.
14. A system for digital rights management, comprising:
(a) a server for storing encrypted digital data; and
(b) a user platform including:
(i) an integrated circuit that includes:
(A) a processor for:
(I) requesting said encrypted digital data from said server, and
(II) decrypting said encrypted digital data, thereby providing decrypted digital data, and
(B) a player for transforming said decrypted digital data to analog signals, and
(ii) a flash memory for storing said encrypted digital data;
wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
15. The system of claim 14, wherein said requesting of said encrypted digital data from said server includes authenticating said integrated circuit to said server.
16. The system of claim 14, wherein said integrated circuit is tamper resistant.
17. The system of claim 14, wherein said user platform further includes:
(ii) a transceiver for transmitting to said server a request for said encrypted digital data and for receiving said encrypted digital data.
18. The system of claim 14, wherein said user platform further includes:
(ii) a display mechanism for displaying said analog signals.
19. The system of claim 14, wherein said integrated circuit includes a single said processor.
20. The system of claim 14, wherein said server is configured to transmit substantially only said encrypted digital data to said user platform.
21. The system of claim 14, wherein said integrated circuit further includes:
(C) a ROM for storing management code that is executed by said processor to operate said integrated circuit.
22. The system of claim 21, wherein said management code is stored only in said ROM.
23. A digital rights management method comprising the steps of:
(a) storing encrypted digital data at a server;
(b) providing an integrated circuit that includes:
(i) a processor operative to:
(A) request said encrypted digital data from the server and
(B) decrypt said encrypted digital data, thereby providing decrypted digital data, and
(ii) a player operative to transform said decrypted digital data to analog signals;
(c) requesting said encrypted digital data from the server, by said processor;
(d) decrypting said encrypted digital data, by said processor, thereby providing said decrypted digital data;
(e) transforming said decrypted digital data to analog signals, by said player; and
(f) storing said encrypted digital data in a flash memory;
wherein decrypting includes the use of a decryption key stored in flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
24. The method of claim 23, wherein said requesting includes authenticating said integrated circuit to the server.
25. The method of claim 24, wherein said authenticating is effected using an asymmetrical algorithm.
26. The method of claim 25, wherein said asymmetrical algorithm is a RSA algorithm.
27. The method of claim 25, wherein said asymmetrical algorithm is a ECC algorithm.
28. The method of claim 23, wherein said decrypting is effected using a symmetrical algorithm.
29. The method of claim 28, wherein said symmetrical algorithm is a DES algorithm.
30. The method of claim 28, wherein said symmetrical algorithm is a Rijndael algorithm.
31. The method of claim 23, wherein said decrypting is effected using at least one key, and wherein the method further comprises the step of:
(g) requesting said at least one key from the server, by said processor.
32. The method of claim 31, wherein the method further comprises the step of:
(h) storing said at least one key in a nonvolatile memory.
33. The method of claim 32, further comprising the step of:
(i) encrypting said at least one key, prior to said storing of said at least one key in said nonvolatile memory.
34. The method of claim 31, further comprising the step of:
(h) configuring the server to send substantially only the encrypted digital data and said at least one key to said integrated circuit.
35. The method of claim 23, further comprising the step of:
(g) upon detecting an attempt to tamper with said integrated circuit: resetting said integrated circuit.
36. The method of claim 23, further comprising the step of:
(g) configuring the server to send substantially only the encrypted digital data to said integrated circuit.
37. The system of claim 14, wherein said digital data are audio data.
38. The system of claim 14, wherein said digital data are video data.
39. The method of claim 23, wherein said encrypted digital data are audio data.
40. The method of claim 23, wherein said encrypted digital data are video data.
41. A device for digital rights management, comprising:
(a) a memory; and
(b) an integrated circuit, separate from said memory, and including:
(i) a processor for:
(A) requesting encrypted digital data from a server,
(B) receiving said requested encrypted digital data,
(C) storing said requested encrypted digital data in said memory, and
(D) decrypting said requested encrypted digital data, thereby providing decrypted digital data, and
(ii) a player for transforming said decrypted digital data to analog signals;
wherein decrypting includes the use of a decryption key stored in the memory, and wherein the decryption key stored in the memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the memory and the integrated circuit are packaged together in a common package.
42. A system for digital rights management, comprising:
(a) a server for storing encrypted digital data; and
(b) a user platform including:
(i) a memory, and
(ii) an integrated circuit, separate from said memory, and including:
(A) a processor for:
(I) requesting said encrypted digital data from the server,
(II) receiving said requested encrypted digital data,
(III) storing said requested encrypted digital data in said memory, and
(IV) decrypting said requested encrypted digital data, thereby providing decrypted digital data, and
(B) a player for transforming said decrypted digital data to analog signals;
wherein decrypting includes the use of a decryption key stored in the memory, and wherein the decryption key stored in the memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the memory and the integrated circuit are packaged together in a common package.
43. A device for digital rights management, comprising:
(a) a nonvolatile memory; and
(b) an integrated circuit, separate from said nonvolatile memory, and including:
(i) a processor for:
(A) requesting encrypted digital data and at least one key from a server,
(B) storing said at least one key in said nonvolatile memory, and
(C) decrypting said encrypted digital data, using said at least one key, thereby providing decrypted digital data, and
(ii) a player for transforming said decrypted digital data into analog signals;
wherein the at least one key is stored in the nonvolatile memory, and wherein the at least one key stored in the nonvolatile memory is encrypted with a unique key stored in the integrated circuit; and
wherein the nonvolatile memory and the integrated circuit are packaged together in a common package.
44. A system for digital rights management, comprising:
(a) a server for storing encrypted digital data and at least one key; and
(b) a user platform including:
(i) a nonvolatile memory, and
(ii) an integrated circuit, separate from said nonvolatile memory, and including:
(A) a processor for:
(I) requesting said encrypted digital data and said at least one key from said server,
(II) storing said at least one key in said nonvolatile memory, and
(III) decrypting said encrypted digital data, using said at least one key, thereby providing decrypted digital data, and
(B) a player for transforming said decrypted digital data to analog signals;
wherein the at least one key is stored in the nonvolatile memory, and wherein the at least one key stored in the nonvolatile memory is encrypted with a unique key stored in the integrated circuit; and
wherein the memory and the integrated circuit are packaged together in a common package.
45. An integrated circuit for digital rights management, comprising:
(a) a processor for:
(i) requesting encrypted digital data from a server,
(ii) receiving said encrypted digital data from said server, and
(iii) decrypting said encrypted digital data only after all said encrypted digital data have been received from said server, wherein decrypting said encrypted digital data results in decrypted digital data; and
(b) a player for transforming said decrypted digital data to analog signals;
wherein decrypting includes the use of a decryption key stored in a memory in communication with said processor, and wherein the decryption key stored in the memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the memory and the integrated circuit are packaged together in a common package.
46. A system for digital rights management, comprising:
(a) a server for storing encrypted digital data; and
(b) a user platform, for playing said encrypted digital data, the user platform including an integrated circuit that includes:
(i) a processor for:
(A) requesting said encrypted digital data from said server,
(B) receiving said encrypted digital data from said server, and
(C) decrypting said encrypted digital data only after all said encrypted digital data have been received from said server, wherein decrypting said encrypted digital data results in decrypted digital data, and
(ii) a player for transforming said decrypted digital data to analog signals;
wherein decrypting includes the use of a decryption key stored in a memory in the user platform, and wherein the decryption key stored in the memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the memory and the integrated circuit are packaged together in a common package.
47. A digital rights management method, comprising:
utilizing an integrated circuit which is coupled to a flash memory device and includes a processor and a player, the player connected to the processor via a bus internal to the integrated circuit, the integrated circuit being utilized by, under control of the processor:
(i) requesting encrypted digital data, the encrypted digital data being received and stored in the flash memory device in encoded format,
(ii) retrieving the encrypted digital data from the flash memory device and producing decrypted digital data by decrypting the retrieved encrypted digital data,
(iii) producing decoded-decrypted digital data by decoding the decrypted digital data, and
(iv) sending the decoded-decrypted digital data to the player where it is transformed to analog signals, wherein sending the decoded-decrypted digital data to the player via the bus internal to the integrated circuit inhibits interception of the decoded-decrypted digital data to prevent illegal copying of the decoded-decrypted digital data;
wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
48. The method of claim 47, wherein the flash memory device is separate from the integrated circuit.
49. A method for digital rights management comprising:
in a device with a flash memory and an integrated circuit, wherein the flash memory is separate from the integrated circuit,
(a) utilizing the integrated circuit to:
(A) retrieve encrypted digital data from the flash memory, the encrypted data being encoded,
(B) produce decrypted digital data by decrypting the encrypted digital data, and
(C) produce decoded digital data by decoding the decrypted digital data, and
(b) utilizing the integrated circuit to transform the decoded digital data to analog signals,
wherein utilizing the integrated circuit inhibits interception of the decoded digital data to prevent illegal copying of the decoded digital data, wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
50. The method of claim 49, further comprising:
utilizing the integrated circuit to:
request the encrypted digital data including authenticating the device to a source of the encrypted digital data, and
store the encrypted digital data, once received, in the flash memory, the encrypted digital data being received and stored in the flash memory in encoded format.
51. The method of claim 50, additionally comprising:
utilizing the integrated circuit to:
monitor for tampering with at least the integrated circuit, and
in response to detecting tampering with at least the integrated circuit, reset at least the integrated circuit.
52. The method of claim 50, wherein utilizing the integrated circuit includes utilizing a processor in the integrated circuit controlled by management code stored in a non-volatile memory in the integrated circuit.
53. The method of claim 52, wherein utilizing the integrated circuit to decrypt the encrypted digital data includes use of a co-processer on the integrated circuit.
54. The method of any one of claims 49-53, wherein the digital data includes audio data and the analog signals are therefore analog audio signals.
55. The method of claim 54, wherein the analog audio signals are applied to an audio transducer, wherein audible sounds are generated thereby.
56. The method of any one of claims 49-53, wherein the digital data includes video data and the analog signals are therefore analog video signals.
57. The method of claim 56, wherein the analog video signals are applied to a video screen, wherein visible video images are generated thereby.
58. The method of claim 50, wherein an authentication key for authenticating the device to the source of the encrypted digital data is stored in the flash memory.
59. The method of claim 58, wherein the authentication key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit.
60. The method of claim 50, wherein an authentication key for authenticating the device to the source of the encrypted digital data is stored in non-volatile memory in the integrated circuit.
61. The method of claim 49, wherein the integrated circuit includes a processor and a player.
62. A method for digital rights management comprising:
in a device containing a flash memory and an integrated circuit, wherein the flash memory is separate from the integrated circuit,
(a) retrieving by the integrated circuit encrypted data from the flash memory, which encrypted data is encoded; and
(b) outputting analog signals from the integrated circuit, the analog signals being produced within the integrated circuit from the encrypted data by:
(i) producing encoded clear data by decrypting the encrypted data;
(ii) producing clear data by decoding the encoded clear data, and
(iii) transforming the clear data into the analog signals,
wherein producing the analog signals within the integrated circuit inhibits interception of the clear data to prevent illegal copying of the clear data, wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
63. The method of claim 62, wherein the integrated circuit is a tamper-resistant ASIC.
64. The method of claim 62, wherein the integrated circuit includes code.
65. The method of claim 62, wherein the integrated circuit includes a processing means and a player coupled to the processing means via a bus internal to the integrated circuit.
66. The method of claim 65, wherein the processing means includes one or more co-processors.
67. The method as in claim 62, wherein the flash memory and the integrated circuit are contained within the device in a common package.
68. The method as in claim 62, further comprising using the outputted analog signals by a display mechanism.
69. The method of claim 62, wherein the analog signals represent audio.
70. The method of claim 62, wherein the analog signals represent video or audio-video.
71. The method of claim 62, further comprising:
requesting the encrypted data; and
storing the encrypted data in the flash memory, once it is received by the device, the encrypted data being received and stored in encoded format.
72. The method of claim 71, wherein the requesting further includes utilizing the integrated circuit to authenticate the device to a source of the encrypted data.
73. The method of claim 72, wherein the device is authenticated to a server.
74. The method of claim 72, wherein authenticating includes using an authentication key stored in the integrated circuit.
75. The method of claim 72, wherein an authentication key for authenticating the device to the source of the encrypted data is stored in the flash memory.
76. The method of claim 75, wherein the authentication key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit.
77. The method of claim 72, wherein an authentication key for authenticating the device to the source of the encrypted data is stored in non-volatile memory in the integrated circuit.
78. The method of claim 62, wherein decrypting includes the use of a decryption key stored in a non-volatile memory on the integrated circuit.
79. The method of claim 62, additionally comprising receiving at least one decryption key from outside of the device along with the encrypted digital data and storing the received decryption key in a non-volatile memory associated with the integrated circuit.
80. The method of claim 79, wherein the at least one decryption key stored in the non-volatile memory associated with the integrated circuit is encrypted with a unique key stored in non-volatile memory in the integrated circuit.
81. The method of claim 62, wherein the integrated circuit includes a processor and a player.
82. A method of protecting data, the method comprising:
in a portable electronic device with a flash memory and electronic circuits, wherein the flash memory is separate from the electronic circuits, utilizing the electronic circuits to produce analog signals from digital data that is both encrypted and encoded, the analog signals being produced by:
a) retrieving the digital data from the flash memory;
b) producing clear encoded data by decrypting the digital data;
c) producing clear data by decoding the clear encoded data; and
d) transforming the clear data to analog signals useful for delivery to a display mechanism of the portable electronic device,
wherein utilizing the electronic circuits inhibits interception of the clear data and thus prevents unlicensed copying thereof, wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the electronic circuits; and
wherein the flash memory and the electronic circuits are packaged together in a common package.
83. The method of claim 82, further utilizing the electronic circuits to:
e) request the digital data; and
f) store the digital data in the flash memory for subsequent use, the digital data being received in an encrypted, encoded format.
84. The method of claim 83, wherein requesting the digital data further includes utilizing the electronic circuits to authenticate the device to a source of the encrypted data.
85. The method of claim 84, wherein the device is authenticated to a server.
86. The method of claim 83, wherein requesting the digital data includes requesting encrypted and encoded digital data from outside of the device and authenticating the device to a source of the encrypted and encoded digital data.
87. The method of claim 86, wherein authenticating the device includes using an authentication key stored in the device.
88. The method of claim 82, wherein decrypting the read encrypted digital data includes the use of a decryption key stored in a non-volatile memory that is part of the electronic circuits within the device.
89. The method of claim 82, additionally comprising receiving at least one decryption key from outside of the device along with the encrypted digital data and storing the received decryption key in a non-volatile memory that is part of the electronic circuits within the device, and wherein reading the stored digital data from the flash memory and decrypting the read digital data includes reading the at least one decryption key from the non-volatile memory and using the read at least one decryption key to decrypt the read digital data.
90. The method of claim 82, additionally comprising:
monitoring the electronic circuits within the device for tampering therewith, and
in response to detecting tampering with the electronic circuits within the device, resetting the electronic circuits.
91. The method of claim 82, wherein utilizing electronic circuits within the device includes utilizing a processor controlled by management code stored in a non-volatile memory that is part of the electronic circuits.
92. The method of claim 91, wherein decrypting the read encrypted digital data includes use of a co-processer that is part of the electronic circuits within the device.
93. The method of any one of claims 82-92, wherein utilizing the electronic circuits within the device include utilizing the electronic circuits on a single integrated circuit.
94. The method of any one of claims 82-92, wherein the digital data are audio data and the analog signals are therefore analog audio signals.
95. The method of claim 94, wherein the analog audio signals are utilized by the user by applying the analog audio signals to an audio transducer, wherein audible sounds are generated thereby.
96. The method of any one of claims 82-92, wherein the digital data are video data and the analog signals are therefore analog video signals.
97. The method of claim 96, wherein the analog video signals are utilized by the user by applying the analog video signals to a video screen, wherein visible video images are generated thereby.
98. The method of claim 84, wherein an authentication key for authenticating the device to the source of the encrypted data is stored in the flash memory.
99. The method of claim 84, wherein an authentication key for authenticating the device to the source of the encrypted data is stored in non-volatile memory in the electronic circuits.
100. The method of claim 82, additionally comprising receiving the decryption key from outside of the device along with the encrypted digital data and storing the decryption key in the flash memory, and wherein reading the stored digital data from the flash memory and decrypting the read digital data includes reading the decryption key from the flash memory and using the decryption key to decrypt the read digital data.
101. The method of claim 82, wherein the electronic circuits include a processor and a player.
102. A playback device comprising:
a flash memory containing encrypted-encoded data;
electronic circuits adapted to retrieve the encrypted-encoded data from the flash memory and to produce analog signals from the encrypted-encoded data by:
producing clear encoded data by decrypting the encrypted-encoded data;
producing clear data by decoding the clear encoded data; and
producing the analog signals by transforming the clear data to the analog signals; and
an interface for conveying the analog signals to a display mechanism,
wherein the electronic circuits are further adapted to inhibit interception of the clear data and to thus prevent unlicensed copying thereof, and wherein the flash memory is separate from the electronic circuits, wherein decrypting includes the use of a decryption key stored in the flash memory, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the electronic circuits; and
wherein the flash memory and the electronic circuits are packaged together in a common package.
103. The playback device of claim 102, further comprising a display mechanism coupled to the interface, wherein the display mechanism comprises a video or audio-video display mechanism.
104. The playback device of claim 102, further comprising a display mechanism coupled to the interface, wherein the display mechanism comprises an audio display mechanism.
105. The playback device of claim 102, wherein the electronic circuits include a processing mechanism for producing the analog signals.
106. The playback device of claim 105, wherein the processing mechanism includes a processor.
107. The playback device of claim 106, wherein the processing mechanism includes one or more co-processors.
108. The playback device of claim 105, wherein the processing mechanism is adapted for authenticating the playback device to a source of the encrypted-encoded data.
109. The playback device of claim 108, wherein an authentication key for authenticating the playback device to the source of the encrypted-encoded data is stored in the flash memory.
110. The playback device of claim 108, wherein an authentication key for authenticating the playback device to the source of the encrypted-encoded data is stored in non-volatile memory in the electronic circuits.
111. The playback device of claim 102, wherein the electronic circuits include an integrated circuit with a processor and a player.
112. The playback device of claim 111 further comprising a bus internal to the electronic circuits that connects the processor and the player.
113. The playback device of claim 102, wherein the electronic circuits include a processor and a player.
114. A digital rights management method, comprising:
utilizing an integrated circuit which is coupled to a flash memory device and includes a processor and a player, the player connected to the processor via a bus internal to the integrated circuit, the integrated circuit being utilized by, under control of the processor:
(i) retrieving encrypted digital data from the flash memory device and producing decrypted digital data by decrypting the retrieved encrypted digital data,
(ii) producing decoded-decrypted digital data by decoding the decrypted digital data, and
(iii) sending the decoded-decrypted digital data to the player where it is transformed to analog signals, wherein sending the decoded-decrypted digital data to the player via the bus internal to the integrated circuit inhibits interception of the decoded-decrypted digital data to prevent illegal copying of the decoded-decrypted digital data;
wherein decrypting includes the use of a decryption key stored in the flash memory device, and wherein the decryption key stored in the flash memory is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
115. The method of claim 114, wherein the flash memory device is separate from the integrated circuit.
116. An integrated circuit adapted for use in a playback device having a flash memory device, the integrated circuit comprising:
a player;
a bus internal to the integrated circuit; and
a processor connected to the player via the bus, wherein the processor is operative to control the integrated circuit to:
(i) retrieve encrypted digital data from a flash memory device and produce decrypted digital data by decrypting the retrieved encrypted digital data,
(ii) produce decoded-decrypted digital data by decoding the decrypted digital data, and
(iii) send the decoded-decrypted digital data to the player where it is transformed to analog signals, wherein sending the decoded-decrypted digital data to the player via the bus inhibits interception of the decoded-decrypted digital data to prevent illegal copying of the decoded-decrypted digital data;
wherein decrypting includes the use of a decryption key stored in the flash memory device, and wherein the decryption key stored in the flash memory device is encrypted with a unique key stored in non-volatile memory in the integrated circuit; and
wherein the flash memory and the integrated circuit are packaged together in a common package.
117. The integrated circuit of claim 116, wherein the flash memory device is separate from the integrated circuit.
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