Your search keyword '"Mark Kassab"' showing total 11 results

1. Isometric Test Data Compression

Author

Mark Kassab, Chen Wang, Amit Kumar, Sudhakar M. Reddy, Jerzy Tyszer, Elham Moghaddam, Janusz Rajski, and Nilanjan Mukherjee

Subjects

Engineering, business.industry, Real-time computing, Test compression, Automatic test pattern generation, Residual, Fault (power engineering), Computer Graphics and Computer-Aided Design, Encoding (memory), Compression ratio, System on a chip, Electrical and Electronic Engineering, Cube, business, Algorithm, Software

Abstract

This paper introduces a novel test data compression scheme, which is primarily devised for low-power test applications. It is based on a fundamental observation that in addition to low test cube fill rates, a very few specified bits, necessary to detect a fault, are actually irreplaceable, whereas the remaining ones can be placed in alternative locations (scan cells). The former assignments are used to create residual test cubes and, subsequently, test templates. They control a power-aware decompressor and guide automatic test pattern generation to produce highly compressible test patterns through finding alternative assignments. The proposed approach reduces, in a user-controlled manner, scan shift-in switching rates with minimal hardware modifications. It also elevates compression ratios to values typically unachievable through conventional low-power reseeding-based solutions. Experimental results obtained for large industrial designs illustrate feasibility of the proposed test scheme and are reported herein.

Published

2015

2. Scan Test Bandwidth Management for Ultralarge-Scale System-on-Chip Architectures

Author

Jakub Janicki, Mark Kassab, Jerzy Tyszer, Wu-Tung Cheng, Nilanjan Mukherjee, Janusz Rajski, Grady Gilles, Yan Dong, Yu Huang, and Grzegorz Mrugalski

Subjects

Bandwidth management, Engineering, Channel allocation schemes, business.industry, Test compression, Scheduling (computing), Automatic test equipment, Hardware and Architecture, Embedded system, System on a chip, Electrical and Electronic Engineering, business, Software, Communication channel, Data compression

Abstract

This paper presents several techniques employed to resolve problems surfacing when applying scan bandwidth management to large industrial multicore system-on-chip (SoC) designs with embedded test data compression. These designs pose significant challenges to the channel management scheme, flow, and tools. This paper introduces several test logic architectures that facilitate preemptive test scheduling for SoC circuits with embedded deterministic test-based test data compression. The same solutions allow efficient handling of physical constraints in realistic applications. Finally, state-of-the-art SoC test scheduling algorithms are rearchitected accordingly by making provisions for: 1) setting up time-effective test configurations; 2) optimization of SoC pin partitions; 3) allocation of core-level channels based on scan data volume; and 4) more flexible core-wise usage of automatic test equipment channel resources. A detailed case study is illustrated herein with a variety of experiments allowing one to learn how to tradeoff different architectures and test-related factors.

Published

2015

3. Test Time Reduction in EDT Bandwidth Management for SoC Designs

Author

Janusz Rajski, Nilanjan Mukherjee, Jakub Janicki, Grzegorz Mrugalski, Jerzy Tyszer, and Mark Kassab

Subjects

Engineering, Bandwidth management, business.industry, Test compression, Automatic test pattern generation, Computer Graphics and Computer-Aided Design, Automatic test equipment, Embedded system, Encoding (memory), Single-core, System on a chip, Electrical and Electronic Engineering, business, Software, Computer hardware, Communication channel

Abstract

This paper presents novel methods of reducing test time and enhancing test compression for system-on-chip (SoC) designs armed with embedded deterministic test (EDT)-based compression logic. The ability of the proposed scheme to improve the encoding efficiency and test compression, while reducing test application time, is accomplished by appropriate selecting and laying out automatic test equipment channel injectors of every single core EDT-based decompressor as well as appropriate bandwidth management of the entire test procedure combined with new control data optimization techniques. The efficacy of the proposed scheme is validated through experiments on several industrial SoC designs and is reported herein.

Published

2013

4. Hybrid Hierarchical and Modular Tests for SoC Designs

Author

Guoliang Li, Mark Kassab, Janusz Rajski, Qinfu Yang, Yuan Zuo, Yu Huang, Rui Li, and Jun Qian

Subjects

Engineering, Broadcasting (networking), Hierarchical test, Computer architecture, business.industry, System on a chip, Test method, Modular design, Automatic test pattern generation, business, Test (assessment), Communication channel

Abstract

Modular test and hierarchical test of core-based System-on-Chip (SoC) are two widely used SoC test methodologies. In this paper, the hybrid test methodology that incorporates these two together is studied by using an industrial real case. Thorough experimental results are demonstrated to compare various scenarios of the hybrid hierarchical and modular tests for SoC designs. Based on the experimental results, using channel sharing based modular test technology at a group of cores combined with hierarchical test to map the patterns of core groups to the top level would result in the most efficient total test time.

Published

2015

5. Test Compression Improvement with EDT Channel Sharing in SoC Designs

Author

Janusz Rajski, Yu Huang, Jihye Kim, Dongkwan Han, Kun Young Chung, Mark Kassab, Jay Jahangiri, and Wu-Tung Cheng

Subjects

Flexibility (engineering), Engineering, business.industry, Design for testing, Compression (functional analysis), Compression ratio, Design flow, Test compression, Data_CODINGANDINFORMATIONTHEORY, business, Computer hardware, Communication channel

Abstract

This paper proposes an innovative test compression technology for system-on-chip (SoC) designs to share scan input channels across multiple cores which use EDT [1] compression. A new DFT compression architecture is proposed to separate control and data channels such that the control channels can be individually accessible, whereas data channels can be shared among a group of cores. The paper illustrates the benefits of the proposed technology in both the enhancement of compression ratios and the flexibility of test compression planning in a core-based SoC design flow. Experimental results with a few large industrial SoCs demonstrate that using the proposed technology the compression can be improved up to 1.87X.

Published

2014

6. A novel Test Access Mechanism for failure diagnosis of multiple isolated identical cores

Author

Avijit Dutta, Brady Benware, Mark Kassab, Manish Sharma, and Wu-Tung Cheng

Subjects

Scheme (programming language), Engineering, Multi-core processor, business.industry, Parallel computing, Mechanism (engineering), Core (game theory), Nonlinear system, Feature (computer vision), Single-core, System on a chip, business, computer, computer.programming_language

Abstract

This paper introduces a novel Test Access Mechanism (TAM) for chips with multiple isolated identical cores through which all the cores can be tested in parallel and at the same time accurate failure diagnosis can be achieved while requiring similar test resources (tester memory and tester channels) as for a single core. The proposed pipelined architecture relies on forming nonlinear equations on a very limited number of output pins that compress the outputs from the identical cores and solve them off-chip to reproduce the failure information of each core. A very nice feature of the proposed scheme is that the number of observation pins required to achieve a desirable level of diagnostic resolution does not scale with the number of identical cores and can practically be kept constant.

Published

2011

7. Clock control architecture and ATPG for reducing pattern count in SoC designs with multiple clock domains

Author

Tom Waayers, Xijiang Lin, Richard Morren, and Mark Kassab

Subjects

Phase-locked loop, Engineering, Clock control, business.industry, Logic gate, Embedded system, System on a chip, Digital clock manager, Automatic test pattern generation, Architecture, business, Synchronization

Abstract

This paper presents a clock control architecture for designs with multiple clock domains, and a novel mix of existing ATPG techniques as well as novel ATPG enhancements. The combination of the ATPG techniques and the clock control hardware lowers the number of test patterns in a fully automated flow, while maintaining the high coverage that is required nowadays by production test. Experimental results are shown for two industrial designs.

Published

2010

8. At-speed scan test with low switching activity

Author

Elham Moghaddam, Mark Kassab, Sudhakar M. Reddy, and Janusz Rajski

Subjects

Engineering, Steady state (electronics), business.industry, Test vector, Logic gate, Electronic engineering, Test compression, Point (geometry), Automatic test pattern generation, business, Power network design, Algorithm, Electronic circuit

Abstract

This paper presents a novel method to generate test vectors that mimic functional operation from switching activity point of view. The method uses states obtained by applying a number of functional clock cycles starting from the scan-in state of a test vector to fill the unspecified scan cell values in test cubes. Experimental results presented for industrial circuits demonstrate the effectiveness of the proposed method.

Published

2010

9. Test Generation for Designs with On-Chip Clock Generators

Author

Xijiang Lin and Mark Kassab

Subjects

Reduction (complexity), Phase-locked loop, Engineering, business.industry, Embedded system, Test compression, Clock generator, System on a chip, Digital clock manager, Automatic test pattern generation, business, CPU multiplier

Abstract

High performance designs often use the on-chip device PLLs for accurate test clock generation during testing. The on-chip clock generator is designed in a programmable way to facilitate the test generation process and it in turn creates additional constraints for the automatic test pattern generation (ATPG) tool. This paper describes an efficient and effective method to take the hardware restrictions originated from the on-chip clock generators into account in order to avoid generating clock sequences that cannot be produced by hardware. Experimental results on industrial designs show test pattern reduction and/or ATPG run time reduction when compared with the test generation method that enumerates valid clock sequences explicitly and restricts the test generation within enumerated test sequences.

Published

2009

10. OCI: Open Compression Interface

Author

Benoit Nadeau-Dostie, Rohit Kapur, Bruce Cory, Mick Tegethoff, Brion Keller, Mark Kassab, Dwayne Burek, Steve Oakland, and Kee Kim

Subjects

Engineering, Boundary scan, Standardization, business.industry, Interface (computing), Compression (functional analysis), Embedded system, Scan chain, Test compression, System on a chip, Pattern generation, business

Abstract

Before on-chip scan compression, it was possible to use different EDA tool vendors to do scan insertion, pattern generation, and diagnosis. On-chip scan compression changed that use model since each tool vendor supplied a different type of scan compression logic and had tool-specific ways to pass necessary information from scan insertion to pattern generation and from pattern generation to diagnosis. OCI (Open Compression Interface) is a standardization of how the necessary data is passed from test logic insertion to pattern generation to diagnosis such that different vendors can be used for each step independent of the on-chip scan compression logic used. This document discusses the need for OCI and gives a conceptual overview of the OCI standard.

Published

2006

11. Erratum to 'Test Time Reduction in EDT Bandwidth Management for SoC Designs' [Nov 13 1776-1786]

Author

Jerzy Tyszer, Jakub Janicki, Grzegorz Mrugalski, Nilanjan Mukherjee, Mark Kassab, and Janusz Rajski

Subjects

Bandwidth management, Engineering, Automatic test equipment, business.industry, Bandwidth (signal processing), Electrical engineering, Electrical and Electronic Engineering, Arithmetic, business, Computer Graphics and Computer-Aided Design, Software

Abstract

Due to a production error, an incorrect figure was used for Fig. 8 on p. 1781 in the above paper (ibid., vol. 32, no. 11, pp. 1776-1786, Nov. 2013). The correct figure is presented here.

Published

2014