Abstract: A portable media player receives encrypted audio files and an encrypted content key from a central license server on the Internet. The media player supports digital rights management (DRM) by storing the encrypted audio file in its flash memory and disabling copying or playing of the audio file after a copy limit has been reached. The copy limit is a rule that is combined with the content key in a transfer key that can be encrypted together by the license server. The license server can detect cloning of the media player by reading a unique player ID from the player and detecting when too many accounts use the same unique player ID. The content key can be generated from polar coordinates of the unique player ID, player manufacturer, and song genre. A fingerprint sensor on the player can scan and compare the user's fingerprints to further detect cloning.

Abstract: A USB device including a housing and a rear cap that is rotatably connected to the housing to facilitate deploying and retracting a plug connector through a front opening of the housing. The plug connector is fixedly connected onto the front end of a sliding rack assembly that is disposed in housing such that the sliding rack assembly is slidable along a longitudinal axis. The sliding rack assembly includes a carrier including a carrier tray for supporting electronic devices and an elongated positioning rod extending from a rear portion of the carrier tray. The positioning rod is operably engaged with an actuator portion such that manual rotation of the rear cap relative to the housing around the longitudinal axis causes the sliding rack assembly to slide inside the housing between retracted and deployed positions.

Abstract: An extended universal serial bus (USB) card reader device is described herein. In one embodiment, a card reader includes a first extended USB (EUSB) connector to be coupled to an external host system, multiple flash memory card sockets capable of receiving multiple flash memory cards inserted therein, multiple flash controllers coupled to the plurality of flash memory card sockets respectively. The card reader further includes a memory for storing executable code, a processor coupled to each of the flash controllers for executing the executable code to control each of the plurality of flash controllers in order to access the corresponding flash memory card inserted therein. The card reader further includes a second EUSB connector to be coupled to an external EUSB device using the extended USB protocols, which is one of an EUSB slave device and an EUSB hub device. Other methods and apparatuses are also described.

Abstract: Systems and methods for communicating using various protocols through the Secured Digital (SD) physical interface are disclosed. The invention covers, among others, single-mode and multi-mode hosts, single-mode and multi-mode devices, as well as techniques for initializing these hosts and devices in order to facilitate the aforementioned communication.

Abstract: A PCI Express-compatible flash device can include one or more flash memory modules, a controller, and an ExpressCard interface. The controller can advantageously provide PCI Express functionality as well as flash memory operations, e.g. writing, reading, or erasing, using the ExpressCard interface. A PIO interface includes sending first and second memory request packets to the flash device. The first memory request packet includes a command word setting that prepares the flash device for the desired operation. The second memory request packet triggers the operation and includes a data payload, if needed. A DMA interface includes sending the second memory request from the flash device to the host, thereby triggering the host to release the system bus for the DMA operation.

Abstract: A flash memory card includes a differential datapath that enables communications between the flash memory card and a host device to be performed using differential signals. The differential datapath can translate between the differential signals and card-specific signals that control read/write operations to the memory array of the flash memory card. The card-specific signals can be standard MultimediaCard, Secure-Digital card, Memory Stick, or CompactFlash card signals, among others. A host device that provides differential data transfer capability can include a similar differential datapath. By using differential data transfer rather than conventional clocked data transfer, overall data bandwidth between a flash memory card and a host device can be significantly increased, while simultaneously decreasing power consumption and pin requirements.

Abstract: Systems and methods for communicating using various protocols through the Secured Digital (SD) physical interface are disclosed. The invention covers, among others, single-mode and multi-mode hosts, single-mode and multi-mode devices, as well as techniques for initializing these hosts and devices in order to facilitate the aforementioned communication.

Abstract: An MMC/SD core unit includes a PCBA in which all passive components and unpackaged IC chips are attached to a single side of a PCB opposite to the metal contacts. The IC chips include, for example, a controller chip and a flash memory chip, or a single-chip (combined controller/flash memory) chip. Multiple flash IC chips are optionally stacked to increase storage capacity. The IC chip(s) are attached to the PCB by wire bonding or other chip-on-board (COB) technique. The passive components are attached by conventional surface mount technology (SMT) techniques. A molded housing is then formed over the IC chips and passive components such that the device has a uniform thickness. The MMC/SD core unit is then inserted or otherwise mounted in an eternal casing to provide a finished MMC/SD device.

Abstract: A press-push type computer peripheral “flash drive” device includes an elongated (e.g., metal) tubular casing containing a PCBA having a plug connector. A plastic housing assembly includes front and rear cap portions mounted over the open ends of the tubular casing, and a fixed plastic sleeve portion disposed in the tubular casing. The PCBA is secured to a plastic sliding rack structure that is disposed in the tubular casing and includes an actuating button protruding through a slot formed in a wall of the tubular casing. When the actuating button is manually pushed and slid along the slot, a portion of the sliding rack structure slides against the plastic sleeve portion in deploying and retracting the USB connector out of the device.

Abstract: High performance flash memory devices (FMD) are described. According to one exemplary embodiment of the invention, a high performance FMD includes an I/O interface, a FMD controller, and at least one non-volatile memory module along with corresponding at least one channel controller. The I/O interface is configured to connect the high performance FMD to a host computing device The FMD contoller is configured to control data transfer (e.g., data reading, data writing/programming, and data erasing) operations between the host computing device and the non-volatile memory module. The at least one non-volatile memory module, comprising one or more non-volatile memory chips, is configured as a secondary storage for the host computing device. The at least one channel controller is configured to ensure proper and efficient data transfer between a set of data buffers located in the FMD controller and the at least one non-volatile memory module.

Abstract: A Low-power flash-memory device uses a modified Universal-Serial-Bus (USB) 3.0 Protocol to reduce power consumption. The bit clock is slowed to reduce power and the need for pre-emphasis when USB cable lengths are short in applications. Data efficiency is improved by eliminating the 8/10-bit encoder and instead encoding sync and framing bytes as 9-bit symbols. Data bytes are expanded by bit stuffing only when a series of six ones occurs in the data. Header and payload data is transmitted as nearly 8-bits per data byte while framing is 9-bits per symbol, much less than the standard 10 bits per byte. Low-power link layers, physical layers, and scaled-down protocol layers are used. A card reader converter hub allows USB hosts to access low-power USB devices. Only one flash device is accessed, reducing power compared with standard USB broadcasting to multiple devices.

Abstract: An extended universal serial bus (USB) storage device is described herein. According to one embodiment, an extended USB storage device includes a printed circuit board assembly (PCBA) having a flash memory device and a flash controller mounted thereon, and an extended USB connector plug coupled to the PCBA for providing a USB compatible interface between an external device and the flash memory device and the flash controller, wherein the extended USB connector plug includes a first end used to couple to the external device and a second end coupled to the flash memory device and the flash controller. In one embodiment, a front piece (1701) includes a metal case (1706) for shielding and a tongue (1709) with contact pins (1781, 1782) and a rear piece (1702) includes a tip portion (1713) with contacts (1783). When the rear tip portion (1713) is inserted into the front piece the contact pins (1783) engage the contact pins (1781, 1782).

Abstract: A secure flash-card reader reads a user ID from a secure card and finds a matching entry with a hashed password in a user table on the reader. An encrypted key is received from a secure host that hashes and encrypts a password the user types into the host and the user's ID. A card decryption engine uses a random number to decrypt the encrypted key and recover the hashed password and user ID from the secure host, which is compared by a comparator to the hashed password and user ID from the user table. A mismatch causes an access controller to block access to encrypted data on the secure card. Flash data is transferred over a flash-serial buffer bus between flash-card controllers and a RAM buffer. An encryption engine on the flash-serial buffer bus encrypts and decrypts data and connects to a serial engine to the host.

Abstract: A portable USB device with an improved configuration is described herein. According to one embodiment, a portable USB device includes a core unit having a USB plug connector coupled to one or more flash memory devices and a flash controller disposed therein, where the flash controller is capable of exchanging data with a host via the USB plug connector using a bulk-only-transfer protocol. The portable USB device further includes a housing for enclosing the core unit, including a front end opening to allow the USB plug connector to be deployed. The portable USB device further includes a core unit carrier for carrying the core unit for deploying and retracting the core unit, including a slide button to allow a finger of a user to slide the USB plug connector of the core unit in and out of the housing via the front end opening of the housing.

Abstract: A Multi-Media Card/Secure Digital (MMC/SD) single-chip flash device contains a MMC/SD flash microcontroller and flash mass storage blocks containing flash memory arrays that are block-addressable rather than randomly-addressable. MMC/SD transactions from a host MMC/SD bus are read by a bus transceiver on the MMC/SD flash microcontroller. Various routines that execute on a CPU in the MMC/SD flash microcontroller are activated in response to commands in the MMC/SD transactions. A flash-memory controller in the MMC/SD flash microcontroller transfers data from the bus transceiver to the flash mass storage blocks for storage. Rather than boot from an internal ROM coupled to the CPU, a boot loader is transferred by DMA from the first page of the flash mass storage block to an internal RAM. The flash memory is automatically read from the first page at power-on. The CPU then executes the boot loader from the internal RAM to load the control program.

Abstract: A USB device including a housing and a protective cap that are slidably and/or pivotably connected together such that the protective cap is able to slide and/or pivot between an open position, in which a plug connector extending from the front of the housing is exposed for operable coupling to a host system, and a closed position, in which the protective cap is disposed over the front end portion of the housing to protect the plug connector. A pivoting/sliding mechanism is provided on the housing and cap that secures the protective cap to the housing at all times, including during transitional movements of the protective cap between the opened and closed positions.

Abstract: Systems and methods of manufacturing and testing non-volatile memory (NVM) devices are described. According to one exemplary embodiment, a function test during manufacturing of the NVM modules is conducted with a system comprises a computer and a NVM tester coupling to the computer via an external bus. The NVM tester comprises a plurality of slots. Each of the slots is configured to accommodate respective one of the NVM modules to be tested. The NVM tester is configured to include an input/output interface, a microcontroller with associated RAM and ROM, a data generator, an address generator, a comparator, a comparison status storage space, a test result indicator and a NVM module detector. The data generator generates a repeatable sequence of data bits as a test vector. The known test vector is written to NVM of the NVM module under test. The known test vector is then compared with the data retrieved from the NVM module.

Abstract: A USB device including a housing and a protective cap that are slidably and/or pivotably connected together such that the protective cap is able to slide and/or pivot between an open position, in which a plug connector extending from the front of the housing is exposed for operable coupling to a host system, and a closed position, in which the protective cap is disposed over the front end portion of the housing to protect the plug connector. A pivoting/sliding mechanism is provided on the housing and cap that secures the protective cap to the housing at all times, including during transitional movements of the protective cap between the opened and closed positions.

Abstract: A high volume testing/formatting process is provided for Universal Serial Bus-based (USB-based) electronic data flash cards (USB devices) that meets the increasing demand for USB electronic data flash cards (USB devices). A test host is simultaneously coupled to the multiple USB devices (e.g., using a multi-port card reader or a probe fixture), a controller endpoint value is read from each of the USB devices and verified with a known good value, and then testing/formatting is performed on each of the USB devices by writing predetermined data into each USB device in a pipelined manner, then reading out and testing the predetermined data. In one embodiment, the test host implements a special USB driver that blocks standard USB registration procedures upon detecting the plurality of USB devices. Control and/or boot code data are written onto the flash memory device (i.e., instead of being provided on a controller ROM).

Abstract: Briefly, a portable USB flash memory device is disclosed to include a Chip-On-Board COB Printed Circuit Board Assembly PCBA inside. The flash memory device is enclosed inside a housing structure with a sliding button to deploy the USB plug connector external to the housing structure. The flash memory device with Multi-Level-Cell MLC compatible is being able to connect to a host with a Universal Serial Bus USB interface.