Testing of Integrated Circuits is important to ensure the production of fault-free chips. However, testing is becoming cumbersome and expensive due to the increasing complexity of these ICs. Technology development has made it possible to produce chips where a complete system, with an enormous transistor count, operating at a high clock frequency, is placed on a single die - SOC (System-on-Chip). The device size miniaturization leads to new fault types, the increasing clock frequencies enforces testing for timing faults, and the increasing transistor count results in a higher number of possible fault sites. Testing must handle all these new challenges in an efficient manner having a global system perspective.

Test design is applied to make a system testable. In a modular core-based environment where blocks of reusable logic, the so called cores, are integrated to a system, test design for each core include: test method selection, test data (stimuli and responses) generation (ATPG), definition of test data storage and partitioning [off-chip as ATE (Automatic Test Equipment) and/or on-chip as BIST (Built-In Self-Test)], wrapper selection and design (IEEE std 1500), TAM (test access mechanism) design, and test scheduling minimizing a cost function whilst considering limitations and constraint. A system test design perspective that takes all the issues above into account is required in order to develop a globally optimized solution.

SOC test design and its optimization is the topic of this book. It gives an introduction to testing, describes the problems related to SOC testing, discusses the modeling granularity and the implementation into EDA (electronic design automation)tools. The book is divided into three sections: i) test concepts, ii) SOC design for test, and iii) SOC test applications. The first part covers an introduction into test problems including faults, fault types, design-flow, design-for-test techniques such as scan-testing and Boundary Scan. The second part of the book discusses SOC related problems such as system modeling, test conflicts, power consumption, test access mechanism design, test scheduling and defect-oriented scheduling. Finally, the third part focuses on SOC applications, such as integrated test scheduling and TAM design, defect-oriented scheduling, and integrating test design with the core selection process.

This book is essential reading for those wishing to obtain a systems perspective and a broad view on the background, performance and application of the latest developments in HSPA in the context of the demands on today's mobile broadband devices and networks. It takes the reader behind the scenes of 3GPP and provides an easily accessible understanding of the basic principles, the latest steps in the standard's evolution, and the motivations behind the development of standardized features. It covers important topics such as smartphone related features, multi-carrier and multi-antenna operation, interface architecture, heterogeneous networks and HSPA system performance. Offering full coverage of recent developments in HSPA up to Release 13, this book will provide a comprehensive description of one of the dominating standards for mobile broadband. With this book, you will: Get a guided and consistent tour through the evolutionary stages of HSPA Gain an understanding of the 3GPP standardization process, the driving forces behind it, and the need for evolution Learn about the fundamental technology components of a modern wireless communication system, such as basic link level architecture, cellular system behavior, traffic management and scheduling and system management Learn in detail the features of the latest HSPA development up to Release 13 Gain a deep insight into the means by which HSPA performance can be simulated and characterized, the factors that drive the performance of networks and user experience, and the performance expectations for the technology Obtain insight into the telecommunications market and its evolution Learn about current trends and the future direction of HSPA

Testing of Integrated Circuits is important to ensure the production of fault-free chips. However, testing is becoming cumbersome and expensive due to the increasing complexity of these ICs. Technology development has made it possible to produce chips where a complete system, with an enormous transistor count, operating at a high clock frequency, is placed on a single die - SOC (System-on-Chip). The device size miniaturization leads to new fault types, the increasing clock frequencies enforces testing for timing faults, and the increasing transistor count results in a higher number of possible fault sites. Testing must handle all these new challenges in an efficient manner having a global system perspective.

Test design is applied to make a system testable. In a modular core-based environment where blocks of reusable logic, the so called cores, are integrated to a system, test design for each core include: test method selection, test data (stimuli and responses) generation (ATPG), definition of test data storage and partitioning off-chip as ATE (Automatic Test Equipment) and/or on-chip as BIST (Built-In Self-Test)], wrapper selection and design (IEEE std 1500), TAM (test access mechanism) design, and test scheduling minimizing a cost function whilst considering limitations and constraint. A system test design perspective that takes all the issues above into account is required in order to develop a globally optimized solution.

SOC test design and its optimization is the topic of this book. It gives an introduction to testing, describes the problems related to SOC testing, discusses the modeling granularity and the implementation into EDA (electronic design automation) tools. The book is divided into three sections: i) test concepts, ii) SOC design for test, and iii) SOC test applications. The first part covers an introduction into test problems including faults, fault types, design-flow, design-for-test techniques such as scan-testing and Boundary Scan. The second part of the book discusses SOC related problems such as system modeling, test conflicts, power consumption, test access mechanism design, test scheduling and defect-oriented scheduling. Finally, the third part focuses on SOC applications, such as integrated test scheduling and TAM design, defect-oriented scheduling, and integrating test design with the core selection process.