Abstract: A portable USB device 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 multi-level cell (MLC) flash memory devices and an MLC flash controller disposed therein. The device further includes a housing for enclosing the core unit. The device further includes a swivel cap having a top surface and a bottom surface by bending a flat panel into a U-shape block having an opening end, a close end, and two side-openings, where the top and bottom surfaces of the swivel cap include a rivet opening align with each other. The housing having the core unit therein is sandwiched by the swivel cap using a set of rivets through the rivet openings of the housings and the swivel cap. The core unit can be rotated with respect to the rivet set in and out of the swivel cap.

Abstract: An electronic data flash card is accessible by a host system, and includes a flash memory controller and at least one flash memory device coupled to the flash controller. The boot code and control code for the flash memory system (flash card) are stored in the flash memory device during a programming procedure. The flash controller transfers the boot code and control code to a volatile main memory (e.g., random access memory or RAM) at start up or reset making a RAM-based memory system. Boot code and control code are selectively overwritten during a code updating operation. A single flash controller thus supports multiple brands and types of flash memory to eliminate stocking issues.

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: An extended Secure-Digital (SD) card has a second interface that uses some of the SD-interface lines. A card-detection routine on a host can initially use the SD interface to detect extended capabilities and command the card to switch to using the second interface. The extended SD card can communicate with legacy SD hosts using just the SD interface, or extended SD cards using the second interface. Also an extended Universal-Serial Bus (EUSB) host enters a suspend mode rather than polling an EUSB device that is busy performing a memory or other operations. Power is saved since polling is avoided. The busy EUSB device sends a not-yet signal back to the EUSB host to instruct the host to enter the suspend mode. When the EUSB device is ready to continue transfer with the host, the EUSB device wakes up the host by sending a ready signal back to the host.

Abstract: A restrictive multi-level-cell (MLC) flash memory prohibits regressive page-writes. When a regressive page-write is requested, an empty block having a low wear-level count is found, and data from the regressive page-write and data from pages stored in the old block are written to the empty block in page order. The old block is erased and recycled. A two-level look-up table is stored in volatile random-access memory (RAM). A logical page address from a host is divided by a modulo divider to generate a quotient and a remainder. The quotient is a logical block address that indexes a first-level look-up table to find a mapping entry with a physical block address that selects a row in a second-level look-up table. The remainder locates a column in the row in the second-level look-up table. If any page-valid bits above the column pointed to by the remainder are set, the write is regressive.

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 multi-level cell (MLC) flash memory devices and an MLC flash controller disposed therein. 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: Phase-change memory (PCM) cells store data using alloy resistors in high-resistance amorphous and low-resistance crystalline states. The time of the memory cell's set-current pulse can be 100 ns, much longer than read or reset times. The write time thus depends on the write data and is relatively long. A page-mode caching PCM device has a lookup table (LUT) that caches write data that is later written to an array of PCM banks. Host data is latched into a line FIFO and written into the LUT, reducing write delays to the relatively slow PCM. Host read data can be supplied by the LUT or fetched from the PCM banks. A multi-line page buffer between the PCM banks and LUT allows for larger block transfers using the LUT. Error-correction code (ECC) checking and generation is performed for data in the LUT, hiding ECC delays for data writes into the PCM banks.

Abstract: A multi-ring memory controller sends request packets to multiple rings of serial flash-memory chips. Each of the multiple rings has serial flash-memory chips with serial links in a uni-directional ring. Each serial flash-memory chip has a bypassing transceiver with a device ID checker that bypasses serial packets to a clock re-synchronizer and bypass logic for retransmission to the next device in the ring, or extracts the serial packet to the local device when an ID match occurs. Serial packets pass through all devices in the ring during one round-trip transaction from the controller. The average latency of one round is constant for all devices on the ring, reducing data-dependent performance, since the same packet latency occurs regardless of the data location on the ring. The serial links can be a Peripheral Component Interconnect (PCI) Express bus. Packets have modified-PCI-Express headers that define the packet type and data-payload length.

Abstract: Phase-change memory (PCM) cells store data using alloy resistors in high-resistance amorphous and low-resistance crystalline states. The time of the memory cell's set-current pulse can be 100 ns, much longer than read or reset times. The write time thus depends on the write data. The very long write-1 time may require wait states. To eliminate wait states for sequential accesses, the PCM cells are divided into 16 banks. Each bank has its own bank write latch that stores data locally at the bank while the bank is being written. Data lines to the banks are freed up to transfer data to other banks once the data is written into the local bank write latch, allowing the long set-current pulse to be applied locally to slowly grow crystals in the alloy resistors. External host data are buffered and applied to the data lines by an array data mux.

Abstract: Peripheral devices store data in non-volatile phase-change memory (PCM). PCM cells have alloy resistors with high-resistance amorphous states and low-resistance crystalline states. The peripheral device can be a Serial AT-Attachment (SATA) or integrated device electronics (IDE) PCM solid-state disk or a Multi-Media Card/Secure Digital (MMC/SD) card. A peripheral PCM controller accesses PCM mass storage devices containing PCM memory chips that form a mass-storage device that is block-addressable rather than randomly-addressable. SATA, IDE, or MMC/SD transactions from a host bus are read by a bus transceiver on the peripheral PCM controller. Various routines that execute on a CPU in the peripheral PCM controller are activated in response to commands in the host-bus transactions. A PCM controller in the peripheral controller transfers data from the bus transceiver to the PCM mass storage devices for storage.

Abstract: Phase-change memory (PCM) cells store data using alloy resistors in high-resistance amorphous and low-resistance crystalline states. The time of the memory cell's set-current pulse can be 100 ns, much longer than read or reset times. The write time thus depends on the write data. The very long write-1 time may require wait states. To eliminate wait states for sequential accesses, the PCM cells are divided into 16 banks. Each bank has its own bank write latch that stores data locally at the bank while the bank is being written. Data lines to the banks are freed up to transfer data to other banks once the data is written into the local bank write latch, allowing the long set-current pulse to be applied locally to slowly grow crystals in the alloy resistors. External host data are buffered and applied to the data lines by an array data mux.

Abstract: Phase-change memory (PCM) cells store data using alloy resistors in high-resistance amorphous and low-resistance crystalline states. The memory cell's reset current can be double a set current, causing peak currents to depend on write data. When all data bits are reset to the amorphous state, a very high peak current is required. To reduce this worst-case peak current, the data is encoded before storage in the PCM cells. An 8/10 encoder adds 2 bits but ensures that no more than half of the data bits are reset. An 8/9 encoder adds an indicator bit, and inverts the 8 bits to ensure that no more than half of the bits are reset. The indicator bit indicates when the 8 bit are inverted, and when the 8 bits are uninverted. Peak currents are thus reduced by encoding to reduce reset data bits.

Abstract: A personal computer motherboard has a main memory of phase-change-memory (PCM) chips in PCM memory modules. An operating system (OS) image is stored in the PCM memory modules and is retained during suspend since the PCM chips are non-volatile. The microprocessor can directly read the OS image retained in the PCM memory modules without copying an OS image from a hard disk to the main memory upon resume. Therefore a boot loader program in the boot ROM does not have to be fetched to the microprocessor for suspend/resume. The video memory can also be PCM, allowing the frame buffer to be retained during suspend/resume, yet be directly addressable by the microprocessor. The display is quickly activated since the frame buffer does not have to be re-constructed after suspend/resume. PCM cells use amorphous and crystalline states of a variable resistor to store data.

Abstract: An extended Universal-Serial-Bus (USB) connector plug and socket each have a pin substrate with one surface that supports the four metal contact pins for the standard USB interface. An extension of the pin substrate carries another 8 extension metal contact pins that mate when both the connector plug and socket are extended. The extension can be an increased length of the plug's and socket's pin substrate or a reverse side of the substrate. Standard USB connectors do not make contact with the extension metal contacts that are recessed, retracted by a mechanical switch, or on the extension of the socket's pin substrate that a standard USB connector cannot reach. Standard USB sockets do not make contact with the extension metal contacts because the extended connector's extension contacts are recessed, or on the extension of the connector pin substrate that does not fit inside a standard USB socket.

Abstract: Phase-change memory (PCM) cells store data using alloy resistors in high-resistance amorphous and low-resistance crystalline states. The memory cell's reset current can be double a set current, causing peak currents to depend on write data. When all data bits are reset to the amorphous state, a very high peak current is required. To reduce this worst-case peak current, the data is encoded before storage in the PCM cells. An 8/10 encoder adds 2 bits but ensures that no more than half of the data bits are reset. An 8/9 encoder adds an indicator bit, and inverts the 8 bits to ensure that no more than half of the bits are reset. The indicator bit indicates when the 8 bit are inverted, and when the 8 bits are un-inverted. Peak currents are thus reduced by encoding to reduce reset data bits.

Abstract: A portable USB device 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 multi-level cell (MLC) flash memory devices and an MLC flash controller disposed therein. The device further includes a housing for enclosing the core unit. The device further includes a swivel cap having a top surface and a bottom surface by bending a flat panel into a U-shape block having an opening end, a close end, and two side-openings, where the top and bottom surfaces of the swivel cap include a rivet opening align with each other. The housing having the core unit therein is sandwiched by the swivel cap using a set of rivets through the rivet openings of the housings and the swivel cap. The core unit can be rotated with respect to the rivet set in and out of the swivel cap.

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 multi-level cell (MLC) flash memory devices and an MLC flash controller disposed therein. 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: An electronic data flash card includes a processor and at least one flash memory device. The flash memory is partitioned such that it includes a first partition that is formatted using a file system that supports an Autorun function (e.g., CD-ROM file system (CDFS) format, fixed-disk format or Universal Disk Format (UDF)), and a disk partition that is formatted using a typical controller-based flash device file system (e.g., 16-bit File Allocation Table (FAT16) file system, 32-bit FAT (FAT32) file system, or New Technology File System (NTFS)). The electronic data flash card is produced such that Autorun-enabled application automatically executes a predetermined application or action when the electronic data flash card is installed in a host system. In one embodiment, the Autorun application includes an advertisement displayed on the host system prior to allowing access to data stored in the disk partition.