Synopses & Reviews
With the increasing demand for higher data bandwidth, communication systems' data rates have reached the multi-gigahertz range and even beyond. Advances in semiconductor technologies have accelerated the adoption of high-speed serial interfaces, such as PCI-Express, Serial-ATA, and XAUI, in order to mitigate the high pin-count and the data-channel skewing problems. However, with the increasing number of I/O pins and greater data rates, significant challenges arise for testing high-speed interfaces in terms of test cost and quality, especially in high volume manufacturing (HVM) environments. Efficient Test Methodologies for High-Speed Serial Links describes in detail several new and promising techniques for cost-effectively testing high-speed interfaces with a high test coverage. One primary focus of Efficient Test Methodologies for High-Speed Serial Links is on efficient testing methods for jitter and bit-error-rate (BER), which are widely used for quantifying the quality of a communication system. Various analysis as well as experimental results are presented to demonstrate the validity of the presented techniques.
Synopsis
Covering new and promising techniques for cost-effectively testing high-speed interfaces with high test coverage, the authors focus on efficient test methodologies for jitter and bit-error-rate, widely used for assessing the quality of communication systems.
Synopsis
Efficient Test Methodologies for High-Speed Serial Links describes in detail several new and promising techniques for cost-effectively testing high-speed interfaces with a high test coverage. One primary focus of Efficient Test Methodologies for High-Speed Serial Links is on efficient testing methods for jitter and bit-error-rate (BER), which are widely used for quantifying the quality of a communication system. Various analysis as well as experimental results are presented to demonstrate the validity of the presented techniques.
Table of Contents
Chapter 1 Intorduction. 1 Overview of High-Speed Serial Links. 1.1 High-Speed Serial Link System. 1.2 Testing High-Speed Serial Links. 2 Challenges in Testing High-Speed Serial Links. 3 Contributions of the Dissertation. Chapter 2 An Efficient Jitter Measurement Technique. 1 Comparator Undersampling Technique. 2 Random Jitter Measurement. 2.1 Proposed RJ Measurement Technique. 2.2 Limitations of the Technique. 3 Experimental Results. 3.1 Simulation Results. 3.2 Measurement Results. 4 Summary. Chapter 3 BER Estimation for Linear Clock and Data Recovery Circuit. 1 BER Analysis with Random Jitter. 1.1 Error Occurrences. 1.2 BER Estimation with Random Jitter. 2 BER Analysis with Random Jitter and Periodic Jitter. 2.1 Jitter Transfer Characteristics of a CDR Circuit. 2.2 BER Estimation with RJ and PJ. 3 BER Analysis Including Intrinsic Noise in the CDR Circuit. 4 Experimental Results. 4.1 Simulation Results. 4.2 Hardware Validation Results. 5 Summary and Future Work. Chapter 4 BER Estimation for Non-Linear Clock and Data Recovery Circuit. 1 Jitter Analysis for BB CDR Circuits. 1.1 Jitter Transfer Analysis. 1.2 Jitter Tolerance Analysis. 2 BER Estimation. 2.1 Variation of Jitter Transfer due to RJ. 2.2 BER Estimation. 3 Experimental Setup and Results. 3.1 Simulation Setup. 3.2 Simulation Results. 4 Summary. Chapter 5 Gaps in Timing Margining Test. 1 Timing Margining Test Basics. 2 Gap Analysis in Timing Margining Test. 2.1 Random Jitter. 2.2 PLL-Based Clock Recovery with Non-Linear Phase Detector. 2.3 Jitter Amplification. 2.4 Duty Cycle Distortion in Clock. 3 Summary and Future Work. Chapter 6 An Accurate Jitter Estimation Technique. 1 Characteristics of DJ. 1.1 ISI Induced Jitter. 1.2 Crosstalk Induced Jitter. 2 Total Jitter Estimation. 2.1 Estimation Based on Dual-Dirac Model. 2.2 High-Order Polynomial Fitting. 2.3 Accuracy vs. Number of Samples for Fitting. 3 Summary. Chapter 7 A Two-Tone Test Method for Continuous-Time Adaptive Equalizers. 1 Continous-Time Adaptive Equalizer. 2 Proposed Two-Tone Test Method. 2.1 Description of the Test Method. 2.2 Implementation of the Test Method. 3 Experimental Results. 3.1 MATLAB Simulation Results. 3.2 Transistor-Level Simulation Results. 4 Summary and Future Work. Chapter 8 Conclusions. Appendix A. References .