Investigation into voltage and process variation-aware manufacturing test

Increasing integration and complexity in IC design provides challenges for manufacturing testing. This thesis studies how process and supply voltage variation influence defect behaviour to determine the impact on manufacturing test cost and quality. The focus is on logic testing of static CMOS designs with respect to two important defect types in deep submicron CMOS: resistive bridges and full opens. The first part of the thesis addresses testing for resistive bridge defects in designs with multiple supply voltage settings. To enable analysis, a fault simulator is developed using a supply voltage-aware model for bridge defect behaviour. The analysis shows that for high defect coverage it is necessary to perform test for more than one supply voltage setting, due to supply voltage-dependent behaviour. A low-cost and effective test method is presented consisting of multi-voltage test generation that achieves high defect coverage and test set size reduction without compromise to defect coverage. Experiments on synthesised benchmarks with realistic bridge locations validate the proposed method.The second part focuses on the behaviour of full open defects under supply voltage variation. The aim is to determine the appropriate value of supply voltage to use when testing. Two models are considered for the behaviour of full open defects with and without gate tunnelling leakage influence. Analysis of the supply voltage-dependent behaviour of full open defects is performed to determine if it is required to test using more than one supply voltage to detect all full open defects. Experiments on synthesised benchmarks using an extended version of the fault simulator tool mentioned above, measure the quantitative impact of supply voltage variation on defect coverage.The final part studies the impact of process variation on the behaviour of bridge defects. Detailed analysis using synthesised ISCAS benchmarks and realistic bridge model shows that process variation leads to additional faults. If process variation is not considered in test generation, the test will fail to detect some of these faults, which leads to test escapes. A novel metric to quantify the impact of process variation on test quality is employed in the development of a new test generation tool, which achieves high bridge defect coverage. The method achieves a user-specified test quality with test sets which are smaller than test sets generated without consideration of process variation

Fault modelling and accelerated simulation of integrated circuits manufacturing defects under process variation

As silicon manufacturing process scales to and beyond the 65-nm node, process variation can no longer be ignored. The impact of process variation on integrated circuit performance and power has received significant research input. Variation-aware test, on the other hand, is a relatively new research area that is currently receiving attention worldwide.Research has shown that test without considering process variation may lead to loss of test quality. Fault modelling and simulation serve as a backbone of manufacturing test. This thesis is concerned with developing efficient fault modelling techniques and simulation methodologies that take into account the effect of process variation on manufacturing defects with particular emphasis on resistive bridges and resistive opens.The first contribution of this thesis addresses the problem of long computation time required to generate logic fault of resistive bridges under process variation by developing a fast and accurate modelling technique to model logic fault behaviour of resistive bridges.The new technique is implemented by employing two efficient voltage calculation algorithms to calculate the logic threshold voltage of driven gates and critical resistance of a fault-site to enable the computation of bridge logic faults without using SPICE. Simulation results show that the technique is fast (on average 53 times faster) and accurate (worst case is 2.64% error) when compared with HSPICE. The second contribution analyses the complexity of delay fault simulation of resistive bridges to reduce the computation time of delay fault when considering process variation. An accelerated delay fault simulation methodology of resistive bridges is developed by employing a three-step strategy to speed up the calculation of transient gate output voltage which is needed to accurately compute delay faults. Simulation results show that the methodology is on average 17.4 times faster, with 5.2% error in accuracy, when compared with HSPICE. The final contribution presents an accelerated simulation methodology of resistive opens to address the problem of long simulation time of delay fault when considering process variation. The methodology is implemented by using two efficient algorithms to accelerate the computation of transient gate output voltage and timing critical resistance of an open fault-site. Simulation results show that the methodology is on average up to 52 times faster than HSPICE, with 4.2% error in accuracy

Testing of leakage current failure in ASIC devices exposed to total ionizing dose environment using design for testability techniques

Due to the advancements in technology, electronic devices have been relied upon to operate under harsh conditions. Radiation is one of the main causes of different failures of the electronics devices. According to the operation environment, the sources of the radiation can be terrestrial or extra-terrestrial. For terrestrial the devices can be used in nuclear reactors or biomedical devices where the radiation is man-made. While for the extra- terrestrial, the devices can be used in satellites, the international space station or spaceships, where the radiation comes from various sources like the Sun. According to the operation environment the effects of radiation differ. These effects falls under two categories, total ionizing dose effect (TID) and single event effects (SEEs). TID effects can be affect the delay and leakage current of CMOS circuits negatively. The affects can therefore hinder the integrated circuits\u27 operation. Before the circuits are used, particularly in critical radiation heavy applications like military and space, testing under radiation must be done to avoid any failures during operation. The standard in testing electronic devices is generating worst case test vectors (WCTVs) and under radiation using these vectors the circuits are tested. However, the generation of these WCTVs have been very challenging so this approach is rarely used for TIDs effects. Design for testability (DFT) have been widely used in the industry for digital circuits testing applications. DFT is usually used with automatic test patterns generation software to generate test vectors against fault models of manufacturer defects for application specific integrated circuit (ASIC.) However, it was never used to generate test vectors for leakage current testing induced in ASICs exposed to TID radiation environment. The purpose of the thesis is to use DFT to identify WCTVs for leakage current failures in sequential circuits for ASIC devices exposed to TID. A novel methodology was devised to identify these test vectors. The methodology is validated and compared to previous non DFT methods. The methodology is proven to overcome the limitation of previous methodologies

Product assurance technology for custom LSI/VLSI electronics

The technology for obtaining custom integrated circuits from CMOS-bulk silicon foundries using a universal set of layout rules is presented. The technical efforts were guided by the requirement to develop a 3 micron CMOS test chip for the Combined Release and Radiation Effects Satellite (CRRES). This chip contains both analog and digital circuits. The development employed all the elements required to obtain custom circuits from silicon foundries, including circuit design, foundry interfacing, circuit test, and circuit qualification

An efficient logic fault diagnosis framework based on effect-cause approach

Fault diagnosis plays an important role in improving the circuit design process and the manufacturing yield. With the increasing number of gates in modern circuits, determining the source of failure in a defective circuit is becoming more and more challenging. In this research, we present an efficient effect-cause diagnosis framework for combinational VLSI circuits. The framework consists of three stages to obtain an accurate and reasonably precise diagnosis. First, an improved critical path tracing algorithm is proposed to identify an initial suspect list by backtracing from faulty primary outputs toward primary inputs. Compared to the traditional critical path tracing approach, our algorithm is faster and exact. Second, a novel probabilistic ranking model is applied to rank the suspects so that the most suspicious one will be ranked at or near the top. Several fast filtering methods are used to prune unrelated suspects. Finally, to refine the diagnosis, fault simulation is performed on the top suspect nets using several common fault models. The difference between the observed faulty behavior and the simulated behavior is used to rank each suspect. Experimental results on ISCAS85 benchmark circuits show that this diagnosis approach is efficient both in terms of memory space and CPU time and the diagnosis results are accurate and reasonably precise

Delay test for diagnosis of power switches

Power switches are used as part of power-gating technique to reduce leakage power of a design. To the best of our knowledge, this is the first work in open-literature to show a systematic diagnosis method for accurately diagnosingpower switches. The proposed diagnosis method utilizes recently proposed DFT solution for efficient testing of power switches in the presence of PVT variation. It divides power switches into segments such that any faulty power switch is detectable thereby achieving high diagnosis accuracy. The proposed diagnosis method has been validated through SPICE simulation using a number of ISCAS benchmarks synthesized with a 90-nm gate library. Simulation results show that when considering the influence of process variation, the worst case loss of accuracy is less than 4.5%; and the worst case loss of accuracy is less than 12% when considering VT (Voltage and Temperature) variations

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

Design for testability of a latch-based design

Abstract. The purpose of this thesis was to decrease the area of digital logic in a power management integrated circuit (PMIC), by replacing selected flip-flops with latches. The thesis consists of a theory part, that provides background theory for the thesis, and a practical part, that presents a latch register design and design for testability (DFT) method for achieving an acceptable level of manufacturing fault coverage for it. The total area was decreased by replacing flip-flops of read-write and one-time programmable registers with latches. One set of negative level active primary latches were shared with all the positive level active latch registers in the same register bank. Clock gating was used to select which latch register the write data was loaded to from the primary latches. The latches were made transparent during the shift operation of partial scan testing. The observability of the latch register clock gating logic was improved by leaving the first bit of each latch register as a flip-flop. The controllability was improved by inserting control points. The latch register design, developed in this thesis, resulted in a total area decrease of 5% and a register bank area decrease of 15% compared to a flip-flop-based reference design. The latch register design manages to maintain the same stuck-at fault coverage as the reference design.Salpaperäisen piirin testattavuuden suunnittelu. Tiivistelmä. Tämän opinnäytetyön tarkoituksena oli pienentää digitaalisen logiikan pinta-alaa integroidussa tehonhallintapiirissä, korvaamalla valitut kiikut salpapiireillä. Opinnäytetyö koostuu teoriaosasta, joka antaa taustatietoa opinnäytetyölle, ja käytännön osuudesta, jossa esitellään salparekisteripiiri ja testattavuussuunnittelun menetelmä, jolla saavutettiin riittävän hyvä virhekattavuus salparekisteripiirille. Kokonaispinta-alaa pienennettiin korvaamalla luku-kirjoitusrekistereiden ja kerran ohjelmoitavien rekistereiden kiikut salpapiireillä. Yhdet negatiivisella tasolla aktiiviset isäntä-salpapiirit jaettiin kaikkien samassa rekisteripankissa olevien positiivisella tasolla aktiivisten salparekistereiden kanssa. Kellon portittamisella valittiin mihin salparekisteriin kirjoitusdata ladattiin yhteisistä isäntä-salpapireistä. Osittaisessa testipolkuihin perustuvassa testauksessa salpapiirit tehtiin läpinäkyviksi siirtooperaation aikana. Salparekisterin kellon portituslogiikan havaittavuutta parannettiin jättämällä jokaisen salparekisterin ensimmäinen bitti kiikuksi. Ohjattavuutta parannettiin lisäämällä ohjauspisteitä. Salparekisteripiiri, joka suunniteltiin tässä diplomityössä, pienensi kokonaispinta-alaa 5 % ja rekisteripankin pinta-alaa 15 % verrattuna kiikkuperäiseen vertailupiiriin. Salparekisteripiiri onnistuu pitämään saman juuttumisvikamallin virhekattavuuden kuin vertailupiiri