MISSED: an environment for mixed-signal microsystem testing and diagnosis

A tight link between design and test data is proposed for speeding up test-pattern generation and diagnosis during mixed-signal prototype verification. Test requirements are already incorporated at the behavioral level and specified with increased detail at lower hierarchical levels. A strict distinction between generic routines and implementation data makes reuse of software possible. A testability-analysis tool and test and DFT libraries support the designer to guarantee testability. Hierarchical backtrace procedures in combination with an expert system and fault libraries assist the designer during mixed-signal chip debuggin

The Fifth NASA Symposium on VLSI Design

The fifth annual NASA Symposium on VLSI Design had 13 sessions including Radiation Effects, Architectures, Mixed Signal, Design Techniques, Fault Testing, Synthesis, Signal Processing, and other Featured Presentations. The symposium provides insights into developments in VLSI and digital systems which can be used to increase data systems performance. The presentations share insights into next generation advances that will serve as a basis for future VLSI design

High-speed Analog-to-digital Converters For Modern Satellite Receivers: Design Verification Test And Sensitivity Analysis

Mixed-signal System-on-chip devices such as analog-to-digital converters (ADCs) have become increasingly prevalent in the semiconductor industry. Since the complexity and applications are different for each device, complex testing and characterization methods are required. Specifically, signal integrity in I/O interfaces requires that standard RF design and test techniques must be integrated into mixed signal processes. While such techniques may be difficult to implement, on-chip test-vehicles and RF circuitry offer the possibility of wireless approaches to chip testing. This would eliminate expensive wafer probing solution to verify the design of high-speed ADC functionality currently required for high-speed product evaluation. This thesis describes a new high-speed analog-to-digital converter test methodology. The target systems used on-chip digital de-multiplexing and clock distribution. A detail sequence of performance testing operations is presented. Digital outputs are post processed and fed into a computer-aided ADC performance characterization tool which is custom-developed in a MATLAB GUI. The problems of high sampling rate ADC testing are described. The test methodologies described reduce test costs and overcome many test hardware limitations. As our focus is on satellite receiver systems, we emphasize the measurement of inter-modulation distortion and effective resolution bandwidth. As a primary characterization component, Fourier analysis is used and we address the issue of sample window adjustment to eliminate spectral leakage and false spur generation. A 6-bit 800 MSamples/sec dual channel SiGe-based ADC is used as a target example and investigated on the corner lot process variations to determine the impact of process variations and the sensitivity of the ADCs to critical process parameter variations

Design of On-Chip Self-Testing Signature Register

Over the last few years, scan test has turn out to be too expensive to implement for industry standard designs due to increasing test data volume and test time. The test cost of a chip is mainly governed by the resource utilization of Automatic Test Equipment (ATE). Also, it directly depends upon test time that includes time required to load test program, to apply test vectors and to analyze generated test response of the chip. An issue of test time and data volume is increasingly appealing designers to use on-chip test data compactors, either on input side or output side or both. Such techniques significantly address the former issues but have little hold over increasing number of input-outputs under test mode. Further, test pins on DUT are increasing over the generations. Thus, scan channels on test floor are falling short in number for placement of such ICs. To address issues discussed above, we introduce an on-chip self-testing signature register. It comprises a response compactor and a comparator. The compactor compacts large chunk of response data to a small test signature whereas the comparator compares this test signature with desired one. The overall test result for the design is generated on single output pin. Being no storage of test response is demanded, the considerable reduction in ATE memory can be observed. Also, with only single pin to be monitored for test result, the number of tester channels and compare edges on ATE side significantly reduce at the end of the test. This cuts down maintenance and usage cost of test floor and increases its life time. Furthermore reduction in test pins gives scope for DFT engineers to increase number of scan chains so as to further reduce test time

Test and Testability of Asynchronous Circuits

The ever-increasing transistor shrinkage and higher clock frequencies are causing serious clock distribution, power management, and reliability issues. Asynchronous design is predicted to have a significant role in tackling these challenges because of its distributed control mechanism and on-demand, rather than continuous, switching activity. Null Convention Logic (NCL) is a robust and low-power asynchronous paradigm that introduces new challenges to test and testability algorithms because 1) the lack of deterministic timing in NCL complicates the management of test timing, 2) all NCL gates are state-holding and even simple combinational circuits show sequential behaviour, and 3) stuck-at faults on gate internal feedback (GIF) of NCL gates do not always cause an incorrect output and therefore are undetectable by automatic test pattern generation (ATPG) algorithms. Existing test methods for NCL use clocked hardware to control the timing of test. Such test hardware could introduce metastability issues into otherwise highly robust NCL devices. Also, existing test techniques for NCL handle the high-statefulness of NCL circuits by excessive incorporation of test hardware which imposes additional area, propagation delay and power consumption. This work, first, proposes a clockless self-timed ATPG that detects all faults on the gate inputs and a share of the GIF faults with no added design for test (DFT). Then, the efficacy of quiescent current (IDDQ) test for detecting GIF faults undetectable by a DFT-less ATPG is investigated. Finally, asynchronous test hardware, including test points, a scan cell, and an interleaved scan architecture, is proposed for NCL-based circuits. To the extent of our knowledge, this is the first work that develops clockless, self-timed test techniques for NCL while minimising the need for DFT, and also the first work conducted on IDDQ test of NCL. The proposed methods are applied to multiple NCL circuits with up to 2,633 NCL gates (10,000 CMOS Boolean gates), in 180 and 45 nm technologies and show average fault coverage of 88.98% for ATPG alone, 98.52% including IDDQ test, and 99.28% when incorporating test hardware. Given that this fault coverage includes detection of GIF faults, our work has 13% higher fault coverage than previous work. Also, because our proposed clockless test hardware eliminates the need for double-latching, it reduces the average area and delay overhead of previous studies by 32% and 50%, respectively