Resistive Switching Memory Architecture Based on Polarity Controllable Selectors

Levisse, Alexandre; Gaillardon, Pierre-Emmanuel; Giraud, B.; O’Connor, Ian; Noel, J. P.; Moreau, Mathieu; Portal, Jean‐Michel

doi:10.1109/tnano.2018.2887140

Cited by 7 publications

(3 citation statements)

References 39 publications

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“…In [8], we explored the opportunities opened by polarity control to design 1Transistor-1RRAM bitcell enabling low voltage reset operation in the context of 2-terminal bipolar RRAM technologies (i.e., filamentary RRAM or STT-MRAM). In [8], both polarity gates were connected together, enabling the transistor to be configured in n-type during a set operation and p-type during a reset operation, thereby enabling a gate-overdrive-free reset operation. In this work, we propose to couple the polarity control with breakthrough array organization schemes.…”

Section: B Polarity Controllable Transistorsmentioning

confidence: 99%

“…Thanks to their three gates, a polarity control can be enabled as introduced section II-B. In that sense, we propose here to use the mechanism demonstrated in [8] to perform bidirectional read operations. horizontal real operations are performed by setting up the TIGFET in n-type, and vertical accesses are performed by setting up the TIGFETs in p-type.…”

Section: B Proposed Architecturementioning

confidence: 99%

“…This new functionality is enabled by the independent use of TIGFET's polarity gates and can be used to enable (i) direct (LSB/MSB) comparisons or (ii) transposed access in the case of 1 word per bitcell (i.e., binarized data or Multiple Level Cells, MLC, RRAM). Finally, SiNWFET-based RRAM array enable strong energy gains [8] and we propose to explore macrolevel consideration regarding sense and write amplifiers overhead.…”

Section: Introductionmentioning

confidence: 99%

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Functionality Enhanced Memories for Edge-AI Embedded Systems

Levisse

Rios

Simon

et al. 2019

2019 19th Non-Volatile Memory Technology Symposium (NVMTS)

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With the surge in complexity of edge workloads, it appeared in the scientific community that such workloads cannot be anymore overflown to the cloud due to the huge edge device to server communication energy cost and the high energy consumption induced in high end server infrastructure. In this context, edge devices must be able to efficiently process complex data-intensive workloads bringing in the concept of Edge AI. However, current architectures show poor energy efficiency while running data intensive workloads. While the community looks toward the integration of new memory architectures using emerging resistive memories and new specific accelerators, we propose a new concept to boost the energy efficiency of Edge systems running data intensive workloads : Functionality Enhanced Memories (FEM). FEM consist on a memory architecture with new functionalities at a decent area overhead cost. In this work, we demonstrate the feasibility of native transpose access for 1Transistor-1RRAM bitcells leveraging three independent gates transistors. Based on that, we thereby propose a concept of FEM-enabled Edge system embedding the proposed native transpose access RRAM-based memory architecture and an in-SRAM computing architecture (the BLADE).

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Section: B Polarity Controllable Transistorsmentioning

confidence: 99%

Section: B Proposed Architecturementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Functionality Enhanced Memories for Edge-AI Embedded Systems

Levisse

Rios

Simon

et al. 2019

2019 19th Non-Volatile Memory Technology Symposium (NVMTS)

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Emerging Memory Structures for VLSI Circuits

Garzón¹,

Yavits²,

Lanuzza³

et al. 2022

Wiley Encyclopedia of Electrical and Electronics Engineering

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Ever since the emergence of the electrical computer and the Von Neumann model, computer architects have adhered to a well‐structured hierarchy of memory solutions, clearly trading off performance and capacity with cost. The ubiquitous memory technologies, dominated by SRAM, DRAM, Flash, and magnetic hard disks, are each situated in a well‐defined location within this hierarchy. However, as processes have scaled into deep nanometer feature sizes and the demand for larger capacities and bandwidths increases, these traditional options face tough challenges and may be limited in their ability to continue to provide the new requirements. New technologies, such as phase change memory (PCM), magnetic RAM (MRAM), and resistive RAM (RRAM), have been researched and developed over the recent past in an attempt to meet these demands and replace some or all of the traditional technologies. In this article, the primary technologies are overviewed, including those that currently fill the memory hierarchy pyramid, the primary candidates to join or replace them in the near‐term, and a number of newer candidates that may arise as legitimate solutions in the farther term. In addition, an overview of the current state of processing within the emerging memory technologies is provided, as an attempt to break free of the traditional Von Neumann paradigm to overcome the energy and performance bottlenecks in modern systems.

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Innovative Memory Architectures Using Functionality Enhanced Devices

Julien

Tang

Gaillardon

2022

Emerging Computing: From Devices to Systems

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Since the introduction of the transistor, the semiconductor industry has always been able to propose an increasingly higher level of circuit performance while keeping cost constant by scaling the transistor’s area. This scaling process (named Moore’s law) has been followed since the 80s. However, it has been facing new constraints and challenges since 2012. Standard sub-30nm bulk CMOS technologies cannot provide sufficient performance while remaining industrially profitable. Thereby, various solutions, such as FinFETs (Auth et al. 2012) or Fully Depleted Silicon On Insulator (FDSOI) (Faynot et al. 2010) transistors have therefore been proposed. All these solutions enabled Moore’s law scaling to continue. However, when approaching sub-10nm technology nodes, the story starts again. Again, process costs and electrical issues reduce the profitability of such solutions, and new technologies such as Gate-All-Around (GAA) (Sacchetto et al. 2009) transistors are seen as future FinFET replacement candidates.

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Resistive Switching Memory Architecture Based on Polarity Controllable Selectors

Cited by 7 publications

References 39 publications

Functionality Enhanced Memories for Edge-AI Embedded Systems

Functionality Enhanced Memories for Edge-AI Embedded Systems

Emerging Memory Structures for VLSI Circuits

Innovative Memory Architectures Using Functionality Enhanced Devices

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