Detecting Unique RRAM Faults: High Fault Coverage Design-For-Testability Scheme

Resistive Random-Access Memory (RRAM) is an emerging memory technology that has the possibility to compete with mainstream memory technologies such as Dynamic Random-Access Memory (DRAM) and flash memory. The reason why RRAM has not seen mass adoption yet is due to its defect-prone nature. The resistance of RRAM can assume any value within its operating range and its resistance can be divided into five states instead of the regular two logic states. Conventional test techniques are incapable of detecting unique faults due to their inability to distinguish between all five cell states, resulting in a large number of test escapes. Therefore, new test methods, such as Design-For-Testability (DFT), need to be developed to reduce the number of test escapes and ensure customer satisfaction. This work proposes two new DFTs: Parallel-Reference Read (PRR) and Closed-Loop Write (CLW). The PRR DFT is a replacement for the regular read circuit, which enables the detection of all five cell states, while the CLW DFT is an addition to the regular write circuit, which introduces feedback during the write operation. From these two DFTs, the PRR DFT is selected for further development and its design is validated. From the validation, it is concluded that the PRR DFT can detect all five cell states. Moreover, under process variations, the PRR DFT will provide the correct output in 95.90% of the cases. Furthermore, the PRR DFT improves the overall resistive-defect detection capability by 14.79% when compared to a regular read circuit. Finally, the PRR DFT offers 100% identified fault coverage while only requiring 4N write operations, 5N read operations and an area overhead of 14Nc transistors, where N and Nc are the total number of cells and the total number of columns in the RRAM array, respectively.Electrical Engineer | Embedded System

An FM Chirp Waveform Generator and Detector for Radar: Sawtooth Generator and FM Detector

The "FM Chirp Waveform Generator and Detector for Radar" is a Bachelor graduation project with an educational purpose. In this thesis, two modules of the whole system are designed and simulated. In particular, the sawtooth generator and the FM detector. The sawtooth generator is used to generate a linearly increasing signal, which can be used to make a chirp signal. The FM detector is used to extract the original information signal from the received FM signal. The used procedure consisted of determining possible implementations, setting up the design equations, choosing component values and simulating the circuits in ADS. The sawtooth generator was implemented using a ramp generator, Schmitt trigger and a voltage clamper while the FM detector was implemented using a balanced slope detector and a differential-to-single-ended converter. The results showed that the sawtooth generator can successfully produce a sawtooth waveform and that the FM detector can successfully retrieve it. It was concluded that both the modules satisfy all the requirements, meaning that they should work as expected in the whole system. Finally, the future steps were listed which, among others, include improving the linearity of the sawtooth generator and the FM detector.An FM Chirp Waveform Generator and Detector for RadarElectrical Engineerin

Online Fault Detection and Diagnosis in RRAM

Resistive Random Access Memory (RRAM, or ReRAM) is a promising memory technology to replace Flash because of its low power consumption, high storage density, and simple integration in existing IC production processes. This has motivated many companies to invest in this technology. However, RRAM manufacturing introduces new failure mechanisms and faults that cause functional errors. These faults cannot all be detected by state-of-the-art test and diagnosis solutions, thus leading to slower product development and low-quality products. This paper introduces a design-for-test (DFT) based on a parallel-multi-reference read (PMRR) circuit that can detect all RRAM array faults. The PMRR circuit replaces the standard sense amplifier and compares the cell’s state to multiple references during one read operation. Thus, it can be used as a DFT scheme and a normal read circuit at once. This allows for speeding up production testing and the online detection of faults. Furthermore, the circuit is extendable so that more references can be compared, which is required for efficient diagnosis. Finally, the references can be adjusted to maximize the production yield. The circuit outperforms state-of-the-art solutions because it can detect all RRAM faults during diagnosis, production testing, and during its application in the field while minimizing yield loss.Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.Computer EngineeringQuantum & Computer Engineerin

Accelerating RRAM Testing with a Low-cost Computation-in-Memory based DFT

Emerging non-volatile resistive RAM (RRAM) device technology has shown great potential to cultivate not only high-density memory storage, but also energy-efficient computing units. However, the unique challenges related to RRAM fabrication process render the traditional memory testing solutions inefficient and inadequate for high product quality. This paper presents low-cost design-for-testability (DFT) solutions that augment the testing process and improve the fault coverage. A computation-in-memory (CIM) based DFT is realized to expedite the detection and diagnosis of faults by developing logic designs involving multi-row activation. A novel addressing scheme is introduced to facilitate the diagnosis of faults. Reconfigurable logic designs are developed to detect unique RRAM faults that offer features such as programmable reference generations, period, and voltage of operation. DFT implementations are validated on a post-layout extracted platform and testing sequences are introduced by incorporating the proposed DFTs. Results show that more than 2.3× speedup and better coverage are achieved with 6× area reduction when compared with state-of-the-art solutions.Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.Computer EngineeringQuantum & Computer Engineerin