Statistical prediction of integrated circuit performance based on circuit design and test structure evaluation

Gibson, David

08 1900

No description available.

Integrated circuits Testing

Integrated circuits Reliability

An intelligence driven test system for detection of stuck-open faults in CMOS sequential circuits

Sagahyroon, Assim Abdelrahman

January 1989

This paper discusses an intelligence driven test system for generation of test sequences for stuck-open faults in CMOS VLSI sequential circuits. The networks in system evaluation are compiled from an RTL representation of the digital system. To excite a stuck-open fault it is only necessary that the output of the gate containing the fault take on opposite values during two successive clock periods. Excitation of the fault must therefore constrain two successive input/present-state vectors, referred to in the paper as the pregoal and goal nodes respectively. An initialization procedure is used to determine the pregoal state. Two theorems are proved establishing a 1-1 correspondence between stuck-at and stuck-open faults. As a result the D-algorithm may be used to determine the goal node. Determining the nodes was tried on many circuits and a high success rate was achieved. The pregoal is observed to have more "don't care" values. The next step is a "sensitization search" for an input sequence (X(s)) that drives the memory elements to the determined pregoal and goal states over two consecutive clock periods. It is easier for the search to reach the pregoal due to the greater number of "don't cares." Following a "propagation search" for an input sequence (X(p)) to drive the effect of the fault to an external output, the sequence of vectors (X(s)), (X(p)) will be passed to an "ALL-Fault Simulator" for verification. The simulation will be clock mode but will represent the output retention resulting from the stuck-open faults. One measure of the value of a special search procedure for stuck-open faults can be obtained by comparing the results employing this search with results obtained by searching only for the analogous stuck-at faults. A first order prediction would be a likelihood less than 0.5 that the predecessor of a stuck-at goal node would excite an opposite output in the gate containing the fault. A comparison of the two methods using the stuck-open "All-Fault Simulator" is presented.

Integrated circuits -- Testing.

Sequential circuits fault simulation using fan out stem based techniques.

Abuelyaman, Eltayeb Salih.

January 1988

This dissertation describes a new simulation technique for an automatic test generation system, SCIRTSS version 4.0 (Sequential Circuit Test Sequence System). This test generation system is driven by the hardware compiler AHPL, a Hardware Programming Language, and an intelligent heuristic-based search for test vector generation. Using a fault-injection gate-level simulator and the generated test vector, all the faulty states of the circuit are simulated in parallel and the simulator is thus able to find all detected faults by a particular input sequence. The major objective of this research was to develop a faster replacement for the existing simulation process. The philosophy of divide and conquer is used in the development of the new simulation technique. Sequential networks are divided into combinational sub-networks, and, if necessary, the combinational sub-networks are further reduced into fan-out free regions. Thus, the problem is reduced to a relatively simple combinational one. In addition to the classical faults, the new simulator attempts to detect CMOS stuck-open faults. Several circuits were tested under SCIRTSS 4.0 using both the existing and the new simulation techniques. The results are listed in this paper to verify superiority of the new simulation technique.

Integrated circuits -- Defects.

Integrated circuits -- Testing.

Computer simulation.

Clock Jitter in Communication Systems

Martwick, Andrew Wayne

21 May 2018

For reliable digital communication between devices, the sources that contribute to data sampling errors must be properly modeled and understood. Clock jitter is one such error source occurring during data transfer between integrated circuits. Clock jitter is a noise source in a communication link similar to electrical noise, but is a time domain noise variable affecting many different parts of the sampling process. Presented in this dissertation, the clock jitter effect on sampling is modeled for communication systems with the degree of accuracy needed for modern high speed data communication. The models developed and presented here have been used to develop the clocking specifications and silicon budgets for industry standards such as PCI Express, USB3.0, GDDR5 Memory, and HBM Memory interfaces.

Integrated circuits -- Testing

Signal processing

Soft errors (Computer science)

Physics

New methodology for low power and less test time in VLSI testing

Lee, Il-Soo

28 August 2008

Not available / text

Integrated circuits--Testing

Test plan generation technique for complex integrated circuits

Lee, Songjun

09 June 2011

Not available / text

Integrated circuits--Testing

FAULT-TEST GENERATION FOR SEQUENTIAL CIRCUITS DESCRIBED IN AHPL

Carter, Ernest Aubert, 1942-

January 1973

No description available.

SCIRTSS (Computer program)

Digital integrated circuits -- Testing.

Electric fault location.

A programmed test sequence generation to detect and distinguish failures in a combinational circuit

Huang, George Huang-Liang, 1938-

January 1973

No description available.

Electric fault location.

Digital integrated circuits -- Testing.

Logic circuits -- Testing.

Efficient testing techniques for analog and mixed-signal circuits

Variyam, Pramodchandran

08 1900

No description available.

Mixed-signal circuits

Integrated circuits Testing

Computer networks

An FPGA-based digital logic core for ATE support and embedded test applications

Davis, Justin S.

08 1900

No description available.

Integrated circuits Testing

Automatic checkout equipment

Field programmable gate arrays