Luigi Dilillo

Dynamic read destructive fault in embedded-SRAMs: analysis and march test solution

This paper presents an analysis of dynamic faults in core-cell of SRAM memories. These faults are the consequence of resistive-open defects that appear more frequently in VDSM technologies. In particular, the study concentrates on those defects that generate dynamic Read Destructive Faults, dRDFs. In this paper, we demonstrate that read or write operations on a cell involve a stress on the other cells of the same word line. This stress, called Read Equivalent Stress (RES), has the same effect than a read operation. On this basis, we propose to modify the well known March C-, which does not detect dRDFs, into a new version able to detect them. This is obtained by changing its addressing order with the purpose of producing the maximal number of RES. This modification does not change the complexity of the algorithm and its capability to detect the former target faults.

Resistive-open defects in embedded-SRAM core cells: analysis and march test solution

In this paper we present an exhaustive analysis of resistive-open defect in core-cell of SRAM memories. These defects that appear more frequently in VDSM technologies induce a modification of the timing within the memory (delay faults). Among the faults induce by such resistive-open defects there are static and dynamic read destructive fault (RDF), deceptive read destructive fault (DRDF), incorrect read fault (IRF) and transition fault (TF). Each of them requires specific test conditions and different kind of March tests are needed to cover all these faults (TF, RDF, DRDF and IRF). In this paper, we show that a unique March test solution can ensure the complete coverage of all the faults induced by the resistive-open defects in the SRAM core-cells. This solution simplifies considerably the problem of delay fault testing in this part of SRAM memories.

A Study of Tapered 3-D TSVs for Power and Thermal Integrity

3-D integration presents a path to higher performance, greater density, increased functionality and heterogeneous technology implementation. However, 3-D integration introduces many challenges for power and thermal integrity due to large switching currents, longer power delivery paths, and increased parasitics compared to 2-D integration. In this work, we provide an in-depth study of power and thermal issues while incorporating the physical design characteristics unique to 3-D integration. We provide a qualitative perspective of the power and thermal dissipation issues in 3-D and study the impact of Through Silicon Vias (TSVs) size for their mitigation. We investigate and discuss the design implications of power and thermal issues in the presence of decoupling capacitors, TSV/on-die/package parasitics, various resonance effects and power gating. Our study is based on a ten-tier system utilizing existing 3-D technology specifications. Based on detailed power distribution and heat dissipation models, we present a comprehensive analysis of TSV tapering for alleviating power and thermal integrity issues in 3-D ICs.

Data retention fault in SRAM memories: analysis and detection procedures

In this paper, we present a novel study on data retention faults (DRFs) in SRAM memories. We analyze in detail the electrical origins of these faults, starting from the most common till those that lead to what we have called hard to detect DRFs. In general, DRFs are supposed to be produced by very high resistive-open defects that affect the refreshment loop of the core-cell. We demonstrate that lower values of resistance may produce hard to detect DRFs. Moreover, each resistive-open defect produces a particular faulty behavior of the core-cell that changes for different ranges of the resistive value. We analyze different cases and we propose for each one an efficient test procedure based on March tests. In particular, we propose to stimulate the defective cells in some cases by indirect accesses and in some other cases by emphasizing natural noise phenomenon of SRAM memories (such as the ground bounce).

March iC-: an improved version of March C- for ADOFs detection

This paper presents a new March test solution for detection of ADOFs (Address Decoder Open Faults), and resistive-ADOFs that are the consequence of resistive-open defects in address decoders of SRAM memories. In this study, we briefly analyze the test conditions and the March test requirements for these particular faults and we introduce some modifications to the well known March C- making it able to detect ADOFs and resistive-ADOFs, without increasing its complexity and its ability to detect the former target faults. The reformulation of March C-, called March iC-, is essentially based on introducing a particular address sequence and a particular read/write data sequence. The proposed March iC- extends the ability of March-based test solutions in detecting dynamic faults in SRAM memories.

Efficient March Test Procedure for Dynamic Read Destructive Fault Detection in SRAM Memories

This paper presents an analysis of dynamic faults in core-cell of SRAM memories. These faults may appear as the consequence of resistive-open defects that appear more and more frequently in VDSM technologies. In particular, the study concentrates on those defects that generate dynamic Read Destructive Faults, dRDFs. In this paper, we demonstrate that read or write operations on a cell involve a stress on the other cells of the same word line. This stress, called Read Equivalent Stress (RES), has the same effect than a read operation. On this basis, we propose to modify the well known March C-, which does not detect dRDFs, into a new version able to detect them. This is obtained by changing its addressing order with the purpose of producing the maximal number of RES. This modification does not change the complexity of the algorithm and its capability to detect the former target faults.

Analysis of Dynamic Faults in Embedded-SRAMs: Implications for Memory Test

This paper presents the results of resistive-open defect insertion in different locations of Infineon 0.13 μm embedded-SRAM with the main purpose of verifying the presence of dynamic faults. This study is based on the injection of resistive defects as their presence in VDSM technologies is more and more frequent. Electrical simulations have been performed to evaluate the effects of those defects in terms of detected functional faults. Read destructive, deceptive read destructive and dynamic read destructive faults have been reproduced and accurately characterized. The dependence of the fault detection has been put in relation with memory operating conditions, resistance value and clock cycle, and the importance of at speed testing for dynamic fault models has been pointed out. Finally resistive Address Decoder Open Faults (ADOF) have been simulated and the conditions that maximize the fault detection have been discussed as well as the resulting implications for memory test.

Testing a Commercial MRAM Under Neutron and Alpha Radiation in Dynamic Mode

Academic and industrial research interest in terrestrial radiation effects of electronic devices has expanded over the last years from avionics and military applications to commercial applications as well. At the same time, the need for faster and more reliable memories has given growth to new memory technologies such as Magnetic (magneto-resistive) Random Access Memories (MRAM), a promising new non-volatile memory technology that will probably replace in the future the current SRAM and FLASH based memories. In this paper, we evaluate the soft error resilience of a commercial toggle MRAM in static and dynamic test mode, under neutron radiation with energies of 25, 50 and 80 MeV as well as under a Californium (Cf-252) alpha source.

Multiple Cell Upset Classification in Commercial SRAMs

While single bit upsets on memories and storage elements are mitigated with either the use of redundancy and/or error correction codes, Multiple-Cell-Upsets (MCU) may become a significant threat to the integrity of systems when the corrupted cells belong to the same word. In this paper, we identify four types of MCUs as they were recorded during several irradiations under an atmospheric-like neutron beam (ISIS facility). An analysis is done on the underlying reasons of occurrence of each MCU type, as well as their shapes and sizes in order to classify them. The results of this work concern a commercial 90 nm SRAM that was tested under an atmospheric neutron beam in static and dynamic mode. It is shown that, when the memory is in dynamic mode, not only the typical MCUs that involve a few flipped cells may appear but also large clusters of upsets are possible to occur with hundreds or even thousands of cells being affected.

Determining Realistic Parameters for the Double Exponential Law that Models Transient Current Pulses

We calculated Single Event Upset (SEU) cross-section as well as the neutron Soft Error Rate (SER) at ground level for three SRAMs (90 nm, 65 nm an 40 nm). For this purpose, we first investigate the transient current pulse induced at each drain electrode, by using the diffusion model for the transient current pulses. Then, we performed the same simulations by replacing each transient current by a simple double exponential law model, for which the parameters were set in order to keep the same fundamental parameters of the diffusion model such as total charge, maximum value of current and its corresponding occurrence time. Our results show a little systematic increase of the cross section while using the double exponential law. Moreover, we showed that only two parameters of the double exponential law are actually required to investigate Single Event Upsets. Finally, we provided for the 90-nm some analytical expression in order to estimate the distribution of parameters that appear in the double exponential law.