0-In's Archer Verification System Targets Verification Hot Spots.Business Editors/High-Tech Writers SAN JOSE San Jose, city, United States San Jose (sănəzā`, săn hōzā`), city (1990 pop. 782,248), seat of Santa Clara co., W central Calif.; founded 1777, inc. 1850. , Calif.--(BUSINESS WIRE)--Jan. 26, 2004 Easy-to-Use Archer Provides Complete Verification Solution for Design Teams Working on Multi-Million Gate 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 SoC Designs Today 0-In Design Automation, the Assertion-Based Verification Company, announced availability of the Archer Verification(TM) system, a complete verification solution that is equal parts tools and engineered methodology for the most critical verification issues facing design teams developing multi-million gate ASIC and system-on-chip (SoC) devices. Archer Verification adds automation to methodologies, providing an efficient, robust and effective set of solutions usable by all design engineers, not just verification specialists. Archer Verification delivers the RTL-centric methods of the verification process automation (VPA VPA Valproate VPA Vancouver Port Authority (Canada) VPA Virtual Population Analysis VPA Voluntary Partnership Agreement VPA Voluntary Placement Agreement VPA Volume Purchase Agreement VPA Vermont Principals' Association ) initiative announced with partners Verisity Ltd. and Novas Software Novas Software was founded in 1996 by Dr. Paul Huang to address the ongoing problem of debugging chip designs. Since then, Novas has grown to employ over 130 people with office locations across the world including Texas, New Hampshire, the United Kingdom, Japan, Korea, India, Inc. (see http://www.0-in.com/news/PR_031103_Strategic_collaboration.html). "Providing verification solutions, rather than simply tools, has allowed us to deploy formal verification
In the context of hardware and software systems, formal verification technologies successfully in many customer projects," said Steve White, 0-In's president and CEO (1) (Chief Executive Officer) The highest individual in command of an organization. Typically the president of the company, the CEO reports to the Chairman of the Board. . "We realized early on that creating a usable, repeatable and effective methodology for using formal technologies is as much engineering work as creating the tools themselves. We have focused on combining first class methods with superior technology to put enormous verification power in the hands of engineers doing the front-line verification work on leading-edge SoC designs." "Throwing only tools or languages at the functional verification Functional verification, in electronic design automation, is the task of verifying that the logic design conforms to specification. In everyday terms, functional verification attempts to answer the question "Does this proposed design do what is intended?" This is a complex task, problem just won't cut it anymore," said Steve Glaser, vice president of corporate marketing and business development for Verisity. "By automating well-defined processes across block, chip, system and project levels, we can truly achieve a 10x boost in productivity -- this is what VPA is all about. With the Archer Verification System, 0-In is clearly helping our joint customers complete their VPA solutions." "The combination of strong tools and an efficient methodology is at the heart of the VPA collaboration between Novas and 0-In," said Dave Kelf, vice-president of marketing for Novas Software. "With the release of the Archer Verification solution, 0-In has truly provided winning assertion-based technology, further delivering on the VPA concept." Faster, Better, Measured Verification The Archer Verification system brings verification closure to users through: -- More efficient verification: finds bugs faster in simulation with assertions and enables more efficient debug To correct a problem in hardware or software. Debugging software means locating the errors in the source code (the program logic). Debugging hardware means finding errors in the circuit design (logical circuits) or in the physical interconnections of the circuits. of errors by quickly identifying the root cause of bugs. -- More complete verification: finds bugs missed by simulation methods alone and automatically exercises corner cases and coverage points. -- Measurable verification closure: uses unified structural coverage to provide measures of verification centered on implementation. "With nearly 20,000 licenses for 0-In products in use, we have a broad range of customer experience on which to draw as we evolve and enhance our product line," said 0-In co-founder and chief architect Richard Ho Richard Ho Man-wui (Chinese: 何文滙) (born 1946), JP, is a Chinese scholar from Hong Kong. After graduating from the University of Hong Kong, he obtained his PhD from the University of London. . "The Archer Verification system leverages that experience to provide comprehensive, packaged solutions that include appropriate tools, verification IP, documentation and co-developed methodologies for specific areas of verification. As customers have told us what works best in the field, we have responded with products that make these methods available to the entire customer base." Platform Independent, Standards-based Technologies The Archer Verification system provides horizontal solutions for functional verification based on comprehensive, easy-to-use and powerful verification IP; a technologically superior toolset and methodologies honed on customer designs. The Archer solutions support all the major verification platforms from EDA (1) (Electronic Design Automation) Using the computer to design, lay out, verify and simulate the performance of electronic circuits on a chip or printed circuit board. vendors including those from Cadence, Verisity, Synopsys and Mentor Graphics Mentor Graphics, Inc (NASDAQ: MENT) is a US-based multinational corporation dealing in electronic design automation (EDA) for electrical engineering and electronics, as of 2004, ranked third in the EDA industry it helped create. . It also supports all emerging assertion standards from Accellera and 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. . By providing platform independent, standards-based advanced functional verification capabilities, Archer gives users the flexibility to choose a simulation infrastructure without sacrificing verification power. Complete and Robust Verification Methodologies Archer Verification is the next evolutionary step for assertion-based and formal verification. The Archer solutions target block, sub-system and chip level functional verification. These solutions enable a complete verification methodology that addresses both specification- and register-transfer level (RTL (Register Transfer Level) A high-level hardware description language (HDL) for defining digital circuits. The circuits are described as a collection of registers, Boolean equations, control logic such as "if-then-else" statements as well as complex event sequences; ) functionality and corner-cases. In particular, Archer provides methods and tools to execute items of the user's verification plan that cannot be addressed in any other way: -- Verification hot spots hot spots acute moist dermatitis. : critical logic that is difficult to verify in simulation. -- Critical coverage points: implementation corner-cases that must be exercised and covered. With Archer Verification, customers are provided with methodologies to verify critical items in their own verification plan. Each methodology applies the most efficient, most complete method and set of tools for each particular verification issue. Coverage metrics are provided to measure progress towards closure. To execute the methodologies efficiently, Archer Verification provides a set of key technologies and capabilities: -- Verification IP - including CheckerWare(R), the industry's most comprehensive library of assertion checkers for RTL structures, as well as an extensive line of more then 25 protocol monitors for standard interfaces and protocols. -- Interoperable assertions in simulation - the ability to use assertions in any of the standard formats including CheckerWare, PSL 1. PSL - Portable Standard Lisp. 2. PSL - Problem Statement Language. See PSL/PSA. , System Verilog and OVL OVL Oval (street type) OVL Open Verification Library OVL Program Overlay (File Name Extension) OVL Oxford Vehicle Leasing (UK) OVL Officier Vlieger . -- Coverage information - actionable implementation-based unified structural coverage to measure progress towards complete verification. -- Formal verification - exhaustive static and dynamic formal verification to unleash enormous computational power for finding bugs missed by simulation. Archer Verification includes structural coverage information that complements functional coverage to provide a complete RTL coverage model. Structural coverage measures verification activity within RTL structures such as arbiters and FIFO (First In First Out) A storage method that retrieves the item stored for the longest time. Contrast with LIFO. See traffic engineering methods. FIFO - first-in first-out buffers based on the corner-cases specific to each structure. For example, structural coverage of a FIFO buffer measures whether the FIFO was empty, full or has reached a high-water mark high-water mark n. 1. Abbr. HWM A mark indicating the highest level reached by a body of water. 2. The highest point, as of achievement; the apex. . The structural coverage metrics are integrated with the CheckerWare library and help users identify areas of their designs that require further verification to find corner-case bugs. Archer Verification also provides a complete exhaustive formal verification capability that includes both static and dynamic formal verification. The Archer Verification methodologies apply formal analysis on verification issues where simulation alone is insufficient. The well-defined methods allow all design and verification engineers to benefit from the power of formal analysis, leading to a predictable improvement in verification time and effort. Archer Verification Products Address Specific Verification Challenges Archer-CDV supports a coverage-driven verification (CDV (1) (Compressed Digital Video) The compression of full-motion video for high-speed, economical transmission. (2) (CD Video) A small videodisc (5" diameter) that provides five minutes of video with digital sound plus an additional 20 minutes ) flow in which metrics are used to gauge the effectiveness of each step in the test plan and to determine which areas of the design need more verification effort. Archer-CDV provides automatic static checks and user-specified assertions running in simulation. Archer-CDV includes the CheckerWare library of verification IP that combines assertion checking with functional coverage collection. CheckerWare library elements also integrate management and debugging (programming) debugging - The process of attempting to determine the cause of the symptoms of malfunctions in a program or other system. These symptoms may be detected during testing or use by real users. capabilities, allowing users to assess both assertion quality and verification completeness. Archer-SF supports a full static formal (SF) verification flow that can find bugs in designs before a simulation environment is available. Archer-SF provides support for automatic design checks and user-specified assertions. These design checks and assertions can be analyzed using formal static verification engines that produce counterexamples showing ways to violate assertions and proofs if no such violations are possible. Integrated formal verification metrics provide feedback on the quality of the assertions as well as the amount of exhaustive formal analysis performed. Archer-ABV supports a chip- or system-level verification flow by providing a complete solution with the full range of assertion-based verification (ABV ABV Above ABV Alcohol By Volume ABV Abuja, Nigeria (airport code) ABV Assault Breacher Vehicle ABV Accredited Business Valuation specialist ABV Auxiliary Building Ventilation ABV Annual Buy Value ABV Air Bleed Valve ) tools and methodologies and by combining exhaustive formal verification with simulation to find bugs missed by all other methods. Archer-ABV includes the capabilities of Archer-SF and Archer-CDV as well as 0-In's unique dynamic formal verification engines to leverage interesting and hard-to-reach corner-cases exercised in chip- or system-level simulations. By applying formal analysis at the right critical moments, RTL bugs can be found that would otherwise reach silicon. Unified coverage metrics from Archer-ABV provide feedback on the quality of the assertions, the degree of design exercised in simulation and the amount of additional coverage provided by the dynamic formal analysis. Pricing and Availability The 0-In Archer Verification System is available immediately. North America North America, third largest continent (1990 est. pop. 365,000,000), c.9,400,000 sq mi (24,346,000 sq km), the northern of the two continents of the Western Hemisphere. list prices are: Archer-CDV $50,000; Archer-SF $60,000; and Archer-ABV $120,000. About 0-In 0-In Design Automation, Inc. (pronounced "zero-in") develops and supports functional verification products that help verify multi-million gate application-specific integrated circuit (hardware) Application-Specific Integrated Circuit - (ASIC) An integrated circuit designed to perform a particular function by defining the interconnection of a set of basic circuit building blocks drawn from a library provided by the circuit manufacturer. (ASIC) and system-on-chip (SoC) designs. The company delivers a comprehensive assertion-based verification (ABV) solution built on industry standards that provides value throughout the design and verification cycle -- from the block level to the chip and system levels. Twelve of the 15 largest electronics companies have adopted 0-In tools and methodologies in their integrated circuit integrated circuit (IC), electronic circuit built on a semiconductor substrate, usually one of single-crystal silicon. The circuit, often called a chip, is packaged in a hermetically sealed case or a nonhermetic plastic capsule, with leads extending from it for (IC) design verification flows. 0-In was founded in 1996 and is based in San Jose, Calif. For more information, see http://www.0-in.com. 0-In(R) and CheckerWare(R) are registered trademarks of 0-In Design Automation, Inc. All other trademarks are the property of their respective holders. |
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