961 research outputs found
Design for pre-bond testability in 3D integrated circuits
In this dissertation we propose several DFT techniques specific to 3D
stacked IC systems. The goal has explicitly been to create techniques that
integrate easily with existing IC test systems. Specifically, this means
utilizing scan- and wrapper-based techniques, two foundations
of the digital IC test industry.
First, we describe a general test architecture for 3D ICs. In this
architecture, each tier of a 3D design is wrapped in test control logic that
both manages tier test
pre-bond and integrates the tier into the large test architecture post-bond.
We describe a new kind of boundary scan to provide the necessary test control
and observation of the partial circuits, and we propose
a new design methodology for test hardcore that ensures both pre-bond functionality
and post-bond optimality. We present the application of these techniques to
the 3D-MAPS test vehicle, which has proven their effectiveness.
Second, we extend these DFT techniques to circuit-partitioned designs. We find
that boundary scan design is generally sufficient, but that some 3D designs require
special DFT treatment. Most importantly, we demonstrate that the functional
partitioning inherent in 3D design can potentially decrease the total test cost
of verifying a circuit.
Third, we present a new CAD algorithm for designing 3D test wrappers. This algorithm
co-designs the pre-bond and post-bond wrappers to simultaneously minimize test
time and routing cost. On average, our algorithm utilizes over 90% of the wires
in both the pre-bond and post-bond wrappers.
Finally, we look at the 3D vias themselves to develop a low-cost, high-volume
pre-bond test methodology appropriate for production-level test. We describe
the shorting probes methodology, wherein large test probes are used to contact
multiple small 3D vias. This technique is an all-digital test method that
integrates seamlessly into existing test flows. Our
experimental results demonstrate two key facts: neither the large capacitance
of the probe tips nor the process variation in the 3D vias and the probe tips
significantly hinders the testability of the circuits.
Taken together, this body of work defines a complete test methodology for
testing 3D ICs pre-bond, eliminating one of the key hurdles to the
commercialization of 3D technology.PhDCommittee Chair: Lee, Hsien-Hsin; Committee Member: Bakir, Muhannad; Committee Member: Lim, Sung Kyu; Committee Member: Vuduc, Richard; Committee Member: Yalamanchili, Sudhaka
DFT and BIST of a multichip module for high-energy physics experiments
Engineers at Politecnico di Torino designed a multichip module for high-energy physics experiments conducted on the Large Hadron Collider. An array of these MCMs handles multichannel data acquisition and signal processing. Testing the MCM from board to die level required a combination of DFT strategie
Recommended from our members
Testability considerations for implementing an embedded memory subsystem
textThere are a number of testability considerations for VLSI design,
but test coverage, test time, accuracy of test patterns and
correctness of design information for DFD (Design for debug) are
the most important ones in design with embedded memories. The goal
of DFT (Design-for-Test) is to achieve zero defects. When it comes
to the memory subsystem in SOCs (system on chips), many flavors of
memory BIST (built-in self test) are able to get high test
coverage in a memory, but often, no proper attention is given to
the memory interface logic (shadow logic). Functional testing and
BIST are the most prevalent tests for this logic, but functional
testing is impractical for complicated SOC designs. As a result,
industry has widely used at-speed scan testing to detect delay
induced defects. Compared with functional testing, scan-based
testing for delay faults reduces overall pattern generation
complexity and cost by enhancing both controllability and
observability of flip-flops. However, without proper modeling of
memory, Xs are generated from memories. Also, when the design has
chip compression logic, the number of ATPG patterns is increased
significantly due to Xs from memories. In this dissertation, a
register based testing method and X prevention logic are presented
to tackle these problems.
An important design stage for scan based testing with memory
subsystems is the step to create a gate level model and verify
with this model. The flow needs to provide a robust ATPG netlist
model. Most industry standard CAD tools used to analyze fault
coverage and generate test vectors require gate level models.
However, custom embedded memories are typically designed using a
transistor-level flow, there is a need for an abstraction step to
generate the gate models, which must be equivalent to the actual
design (transistor level). The contribution of the research is a
framework to verify that the gate level representation of custom
designs is equivalent to the transistor-level design.
Compared to basic stuck-at fault testing, the number of patterns
for at-speed testing is much larger than for basic stuck-at fault
testing. So reducing test and data volume are important. In this
desertion, a new scan reordering method is introduced to reduce
test data with an optimal routing solution. With in depth
understanding of embedded memories and flows developed during the
study of custom memory DFT, a custom embedded memory Bit Mapping
method using a symbolic simulator is presented in the last chapter
to achieve high yield for memories.Electrical and Computer Engineerin
VLSI Testing and Test Power
This paper first reviews the basics of VLSI testing, focusing on test generation and design for testability. Then it discusses the impact of test power in scan testing, and highlights the need for low-power VLSI testing.2011 International Green Computing Conference and Workshops (IGCC 2011), July 25-28, 2011, Orlando, FL, US
A Hardware Security Solution against Scan-Based Attacks
Scan based Design for Test (DfT) schemes have been widely used to achieve high fault coverage for integrated circuits. The scan technique provides full access to the internal nodes of the device-under-test to control them or observe their response to input test vectors. While such comprehensive access is highly desirable for testing, it is not acceptable for secure chips as it is subject to exploitation by various attacks. In this work, new methods are presented to protect the security of critical information against scan-based attacks. In the proposed methods, access to the circuit containing secret information via the scan chain has been severely limited in order to reduce the risk of a security breach. To ensure the testability of the circuit, a built-in self-test which utilizes an LFSR as the test pattern generator (TPG) is proposed. The proposed schemes can be used as a countermeasure against side channel attacks with a low area overhead as compared to the existing solutions in literature
Design-for-delay-testability techniques for high-speed digital circuits
The importance of delay faults is enhanced by the ever increasing clock rates and decreasing geometry sizes of nowadays' circuits. This thesis focuses on the development of Design-for-Delay-Testability (DfDT) techniques for high-speed circuits and embedded cores. The rising costs of IC testing and in particular the costs of Automatic Test Equipment are major concerns for the semiconductor industry. To reverse the trend of rising testing costs, DfDT is\ud
getting more and more important
Efficient Test Set Modification for Capture Power Reduction
The occurrence of high switching activity when the response to a test vector is captured by flipflops in scan testing may cause excessive IR drop, resulting in significant test-induced yield loss. This paper addresses the problem with a novel method based on test set modification, featuring (1) a new constrained X-identification technique that turns a properly selected set of bits in a fullyspecified test set into X-bits without fault coverage loss, and (2) a new LCP (low capture power) X-filling technique that optimally assigns 0’s and 1’s to the X-bits for the purpose of reducing the switching activity of the resulting test set in capture mode. This method can be readily applied in any test generation flow for capture power reduction without any impact on area, timing, test set size, and fault coverage
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
- …