Lattice Semiconductor Introduces Low Power Field-Programmable System-on-a-Chip for SPI4.2 Solutions.Business Editors/High-Tech Writers HILLSBORO, Ore.--(BUSINESS WIRE)--Nov. 17, 2003 ORSPI4 FPSC FPSC Florida Public Service Commission FPSC Financial Planners Standards Council (Canada) FPSC Field Programmable System Chip (Lucent Technologies) FPSC Fundación Promoción Social de la Cultura offers two low-power embedded SPI (1) (Stateful Packet Inspection) See stateful inspection. (2) (Service Provider Interface) The programming interface for developing Windows drivers under WOSA. 4.2, 4 channels of 3.7 Gbps SERDES See serializer/deserializer. , embedded QDR QDR Quadrennial Defense Review (US DoD) QDR Quad Data Rate (Memory Technology) QDR Quality Deficiency Report QDR Quality, Durability and Reliability (Toyota Motor Company) II memory controller plus 16K field programmable logic See PLD. elements Lattice Semiconductor Lattice Semiconductor Corporation (NASDAQ: LSCC) is a United States based manufacturer of high-performance programmable logic devices (FPGAs, CPLDs, & SPLDs). The Oregon based company is the number four ranked company in world market share for FPGA devices,[1] Corporation (Nasdaq:LSCC LSCC Lake-Sumter Community College (Florida) LSCC Lattice Semiconductor Corporation (stock symbol) LSCC Lawson State Community College (Alabama) ), the leader in programmable SERDES technology, today announced the availability of the ORSPI4, a Field Programmable System-on-a-Chip (FPSC) that efficiently integrates ASIC (Application Specific Integrated Circuit) Pronounced "a-sick." A chip that is custom designed for a specific application rather than a general-purpose chip such as a microprocessor. and FPGA (Field Programmable Gate Array) A type of gate array that is programmed in the field rather than in a semiconductor fab. Containing up to hundreds of thousands of gates, there are a variety of FPGA architectures on the market. technologies. By combining the two approaches, Lattice has developed a more highly integrated, higher performance, lower cost and lower power SPI4.2 solution when compared to a full FPGA implementation. The pre-engineered ASIC block on the ORSPI4 contains two SPI4.2 interface blocks, a high-speed Quad Data Rate Quad data rate (or quad pumping) is a communication signalling technique wherein data is transmitted at both the rising and falling edges of the clock signal, much the same way DDR technology works, but with two clock signals 90° out of phase from each other, effectively (QDR II) SRAM See static RAM. SRAM - static random-access memory memory controller, 4 channels of 600 Mbps to 3.7 Gigabits per second (Gbps) SERDES, 8b/10b encoding/decoding and other supporting logic. Connected to the ASIC block is a high performance FPGA with over 16,000 FPGA logic elements plus embedded block RAM. The ORSPI4 FPSC is the world's most highly integrated field programmable System-on-a-Chip targeted at line card applications for high-speed communications systems in the Metro space. "The ORSPI4 FPSC is the tenth FPSC product that Lattice has introduced into the market, but the first targeted specifically at a growing line card segment," said Stan Kopec, vice president of corporate marketing at Lattice. "Analysts expect line card shipments to rise from 1.9 million ports in 2002 to 4.8 million ports in 2006, a 27% compound annual growth rate (CAGR CAGR See: Compound Annual Growth Rate )(1), and Lattice will be there with a highly-integrated device that will bridge network processors, MACs and framers to high-speed serial backplanes," added Kopec. SPI4.2 (System-Packet Interface, Level 4, Phase 2) is a recent system-level interface standard that enables the development of flexible, scalable systems for a converged data and telecommunications infrastructure. Published in 2001 by the Optical Internetworking Forum The Optical Internetworking Forum (OIF) was organized to facilitate and accelerate the development of next-generation optical internetworking products. The OIF produces Electrical, Tunable Laser, Very Short Reach Hardware Interfaces. (OIF OIF Operation Iraqi Freedom OIF Organisation Internationale de la Francophonie (French: International Organization of Francophonie) OIF Office for Intellectual Freedom (American Library Association) ), the SPI4.2 standard supports the transmission of multiple protocols at variable, high-speed data rates, including: Packet-over-SONET/SDH (POS (1) See point of sale and packet over SONET. (2) "Parent over shoulder." See digispeak. POS - point of sale ), OC-192, Ethernet, Fast Ethernet, Gigabit Ethernet, 10 Gigabit Ethernet, and 10 Gigabit Fibre-Channel SAN. SPI4.2 eliminates proprietary ASIC-based or specialized network processor interfaces traditionally used to support a broad range of data rates and services. The benefits are a common standards-based interface facilitating inter-connection between diverse devices from multiple manufacturers. Designed for packet transfer between a MAC device and a network processor or switch fabric, the SPI4.2 interface supports the aggregate bandwidths required of ATM and Packet-over-SONET/SDH (POS) applications. SPI4.2 provides a common interface for 10 Gbps Wide Area Network (WAN), Local Area Network (LAN (Local Area Network) A communications network that serves users within a confined geographical area. The "clients" are the user's workstations typically running Windows, although Mac and Linux clients are also used. ), Metro Area Network (MAN), and Storage Area Network (SAN) technologies, and it is ideal for systems that aggregate low-data rate channels into a single 10 Gbps uplink for long haul or backbone transmission. Lattice's ORSPI4 FPSC is unique in the programmable market as it embeds the SPI4.2 core in pre-characterized ASIC gates, unlike competitors who ship soft SPI4.2 IP cores which must be integrated into the overall design and face the uncertainties of FPGA place and route timing. Advantages Over FPGA-Only Approaches "Unlike other SPI4.2 implementations for FPGAs, the ORSPI4 FPSC embeds all the high-speed functions in an ASIC core of over 1 million gates, allowing the FPGA gates to be used for design-specific bridging functions," commented Stan Kopec, vice president of marketing at Lattice. "Embedding these functions within a hard core assures performance, predictability and interoperability. This implementation also provides a big advantage in terms of total power consumption. Typical programmable-only FPGA IP cores consume upwards of 10W for one SPI4.2 interface implementation. In comparison, the ORSPI4 dissipates less than 2W per SPI4.2 implementation at 900 Mbps operation. This is a big advantage for power hungry 10 Gbps line cards," added Kopec. "Line cards are getting 'smarter' all the time, with the incorporation of NPUs and traffic management capabilities. This intelligence adds to board complexity with the potential for signal skew (1) The misalignment of a document or punch card in the feed tray or hopper that prohibits it from being scanned or read properly. (2) In facsimile, the difference in rectangularity between the received and transmitted page. and strenuous layout constraints," added Kopec. "The SPI4.2 spec defines a de-skew technique that relies on a built-in training sequence with user-selectable repetition rate and duration. Referred to as dynamic alignment, this timing mode eliminates phase errors due to PCB PCB: see polychlorinated biphenyl. PCB in full polychlorinated biphenyl Any of a class of highly stable organic compounds prepared by the reaction of chlorine with biphenyl, a two-ring compound. traces of unequal lengths by continuously monitoring the data and adjusting the phase of the clock to align with it. This can be a challenging problem for programmable devices, but our FPSC technology affords us the opportunity to manage dynamic alignment with predictable and reliable ASIC technology," he concluded.
SPI4.2 Core Features
The SPI4 interface blocks in the ORSPI4 FPSC contains these
industry-best features:
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Multiple SPI4.2 -- Two independent full-featured OIF-compliant
interface cores SPI4.2 interfaces for greater than20 Gbps
bandwidth.
-- Supports quarter-rate mode for 2.5 Gbps
operation
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Data Alignment -- Supports both static and dynamic alignment
schemes
-- Supports dynamic bit de-skew over 16 phases
of clock
-- Supports receive clock aligned or clock
centered transmit data in static mode.
----------------------------------------------------------------------
Parity generation and -- DIP-2 and DIP-4 parity generation and
checking checking embedded in ASIC
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Calendar support -- Embedded 1K deep main and shadow calendar
built-in, supports scheduling up to 256 ports
and hit-less bandwidth provisioning
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User design interface -- User friendly FIFO interface from ASIC to
FPGA logic for clock domain transfer and ease
of design
-- Support of up to four user clock domains
and 32 FIFOs per Tx and Rx
----------------------------------------------------------------------
Signal integrity -- Dedicated LVDS drivers and receivers with
center tap option increases performance and
reduces jitter
----------------------------------------------------------------------
Flow Control -- An embedded set of write and read port
flexibility descriptor memories supports a flexible flow
control interface for each SPI4.2 port
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Low Power -- Less than 2W of power for each SPI4.2
interface at 900 Mbps operation with dynamic
alignment
-- 1.5W for each SPI4.2 interface at 700 Mbps
operation with static alignment
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Packet Buffering -- Embedded high-speed memory controller for
interface to external QDR II SRAM for line-
rate packet buffering
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The SPI4.2 cores on the ORSPI4 FPSC provide dual 10 Gbps Physical-to-Link Layer interfaces in conformance to the OIF-SPI4-02.0 specification. Each block provides a bi-directional interface with an aggregate bandwidth of 14.4 Gbps. This is achieved by using 16 LVDS (Low Voltage Differential Signaling) A transmission method for sending digital information. LVDS sends data over data high and data low lines rather than data and ground. pairs each for transmit and receive channel operating at a data rate of 900 Mbps with a 450 MHz (MegaHertZ) One million cycles per second. It is used to measure the transmission speed of electronic devices, including channels, buses and the computer's internal clock. A one-megahertz clock (1 MHz) means some number of bits (16, 32, 64, etc. DDR (Double Data Rate) Refers to an SDRAM memory chip that increases performance by doubling the effective data rate of the frontside bus. For more details, see SDRAM. DDR - Double Data Rate Random Access Memory clock. Both static and dynamic alignment are supported at the receive interface. DIP-4 and DIP-2 parity generation and checking are also supported. 8K bytes of data buffering is provided by embedded Dual-Port RAM for both transmit and receive in each SPI-4.2 core. Internal 1K deep main and shadow calendars supports scheduling of up to 256 ports. The Transmit and Receive Status FIFOs can also store flow control information for up to 256 ports, the maximum specified in the SPI-4.2 specification. In order to provide wire-speed packet processing, the ORSPI4 also contains an independent Memory Controller Block that provides data buffering between the FPGA logic and external memory and supports a throughput of greater than 20 Gbps. Data is transferred to and from memory through two sets of 36-bit unidirectional The transfer or transmission of data in a channel in one direction only. data lines (one read, one write) operating at up to 200 MHz DDR (400Mbps). A set of 72 data signals is available to transfer data across the core-FPGA interface and allows the system to utilize the bandwidth available with second-generation QDR II SRAMs. Of the 72 data signals, 8 signals can be used either for parity or data. A second memory controller can also be added in the FPGA section to provide two independent line-rate buffers if needed. High Speed SERDES I/O (Input/Output) The transfer of data between the CPU and a peripheral device. Every transfer is an output from one device and an input to another. See PC input/output. I/O - Input/Output The high-speed SERDES block supports four serial links, each operating at up to 3.7 Gbps (2.96 Gbps data rate with 8b/10b encoding and decoding), to provide four full-duplex synchronous interfaces with built-in receiver Clock and Data Recovery (CDR (1) See CD-R and extension. (2) (Call Detail Reporting) See call accounting. (3) (Common Data Rate) A standard sampling rate for digital video for 480i and 576i systems. The rate is 13.5 MHz. See ITU-R BT. ) and transmitter pre-emphasis. The SERDES block is identical to that proven in Lattice's ORT82G5 and ORT42G5 FPSCs, supporting embedded 8b/10b encoding/decoding as well as link state machines for both 10 Gbps Ethernet and Fibre Channel. The state machines are IEEE (Institute of Electrical and Electronics Engineers, New York, www.ieee.org) A membership organization that includes engineers, scientists and students in electronics and allied fields. P802.3ae/D4.01 XAUI XAUI 10 Gigabit Attachment Unit Interface XAUI Extended Auxiliary Unit Interface XAUI XSBI Attachment Unit Interface (IEEE 802.3ae) XAUI Ten Gbps Attachment Unit Interface compliant and also support FC (ANSI (American National Standards Institute, New York, www.ansi.org) A membership organization founded in 1918 that coordinates the development of U.S. voluntary national standards in both the private and public sectors. It is the U.S. member body to ISO and IEC. X3.230: 1994) link synchronization. The SERDES in the ORSPI4 FPSC contains industry-best performance with the following features:
----------------------------------------------------------------------
Widest range of -- 4 channels with industry-leading
Programmable Data Rates performance from 0.6 Gbps to 3.7 Gbps
----------------------------------------------------------------------
Multiple Standards -- Fibre Channel (1G, 2G), XAUI-Ethernet
Compliance (10G) and XAUI-FC (10G)
----------------------------------------------------------------------
Rx Jitter Tolerance -- 0.75UI p-p typical, 0.65 UI p-p worst
case, exceeds XAUI and Fibre Channel
specifications (at 3.125 Gbps)
----------------------------------------------------------------------
Tx Total Jitter -- 0.17UI p-p typical, 0.24 UI p-p worst
case, exceeds XAUI and Fibre Channel
specifications (at 3.125 Gbps)
----------------------------------------------------------------------
Low Power per SERDES -- 225 mW worst case, including I/O buffers
Channel at 3.125 Gbps
----------------------------------------------------------------------
Fast Locking Times -- Bit Realignment 300 nanoseconds (938 bit
times at 3.125 Gbps) nominal
----------------------------------------------------------------------
Transmitter Output (CML) -- Full-amplitude mode: 0.8V p-p Minimum
-- Half-amplitude mode: 0.4V p-p Minimum
----------------------------------------------------------------------
Demonstrated Drive Length -- Over 40 inches (100cm) of FR-4 backplane
----------------------------------------------------------------------
The ORSPI4 FPSC also contains a dedicated microprocessor interface, a 32-bit internal system bus (and 4-bits parity), and built-in system registers that act as the control and status center for the SPI4.2, SERDES, and memory controller blocks. The FPGA portion of the device can also be configured through this interface. Availability The ORSPI4 FPSC in the 1036 fpSBGA (1mm ball pitch, thermally enhanced fine pitch ball grid array “BGA” redirects here. For other uses, see BGA (disambiguation). A ball grid array (BGA) is a type of surface-mount packaging used for integrated circuits. ) package is currently shipping. The unit price in quantities of 10,000 is $250.00. The device will also be offered in an 1156 fpSBGA package without the SERDES channels. The device is supported by Lattice's ispLEVER(R) v3.1 design software, a dedicated design kit, and popular third-party synthesis, simulation, and verification tools. About Lattice Semiconductor Oregon-based Lattice Semiconductor Corporation designs, develops and markets the broadest range of Field Programmable Gate Arrays (FPGAs), Field Programmable System Chips (FPSCs) and high-performance ISP (1) See in-system programmable. (2) (Internet Service Provider) An organization that provides access to the Internet. Connection to the user is provided via dial-up, ISDN, cable, DSL and T1/T3 lines. (TM) programmable logic devices (PLDs). Lattice offers total solutions for today's system designs by delivering the most innovative programmable silicon products that embody leading-edge system expertise. Lattice products are sold worldwide through an extensive network of independent sales representatives and distributors, primarily to OEM (Original Equipment Manufacturer) The rebranding of equipment and selling it. The term initially referred to the company that made the products (the "original" manufacturer), but eventually became widely used to refer to the organization that buys the products and customers in the fields of communication, computing, computer peripherals, instrumentation, industrial controls and military systems. Company headquarters are located at 5555 NE Moore Court, Hillsboro, Oregon 97124 USA; Telephone 503-268-8000, FAX 503-268-8037. For more information on Lattice Semiconductor Corporation, access our World Wide Web site at http://www.latticesemi.com. Statements in this news release looking forward in time are made pursuant to the safe harbor Safe Harbor 1. A legal provision to reduce or eliminate liability as long as good faith is demonstrated. 2. A form of shark repellent implemented by a target company acquiring a business that is so poorly regulated that the target itself is less attractive. provisions of the Private Securities Litigation Reform Act The Private Securities Litigation Reform Act of 1995 (PSLRA) implemented several significant substantive changes affecting certain cases brought under the federal securities laws, including changes related to pleading, discovery, liability, class representation and awards fees and of 1995. Investors are cautioned that forward-looking statements involve risks and uncertainties including market acceptance and demand for our new products, our dependencies on our silicon wafer suppliers, the impact of competitive products and pricing, technological and product development risks and other risk factors detailed in the Company's Securities and Exchange Commission filings. Actual results may differ materially from forward-looking statements. Lattice Semiconductor Corporation, Lattice (& design), L (& design), in-system programmable, ISP, ispLEVER, and specific product designations are either registered trademarks or trademarks of Lattice Semiconductor Corporation or its subsidiaries in the United States and/or other countries. GENERAL NOTICE: Other product names used in this publication are for identification purposes only and may be trademarks of their respective holders. (1)Semiconductors: Technology and Market Primer 1.0, CIBC World Markets CIBC World Markets is the investment banking division of the Canadian Imperial Bank of Commerce. It helps governments, large companies, and other large institutions obtain capital and credit and is a primary dealer in U.S. Treasury securities. Inc., May 30 2003 |
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