Traditional digital processing approaches are based on semiconductor transistors, which suffer from high power consumption, aggravating with technology node scaling. To solve definitively this problem, a number of eme...Traditional digital processing approaches are based on semiconductor transistors, which suffer from high power consumption, aggravating with technology node scaling. To solve definitively this problem, a number of emerging non-volatile nanodevices are under intense investigations. Meanwhile, novel computing circuits are invented to dig the full potential of the nanodevices. The combination of non-volatile nanodevices with suitable computing paradigms have many merits compared with the complementary metal-oxide-semiconductor transistor (CMOS) technology based structures, such as zero standby power, ultra-high density, non-volatility, and acceptable access speed. In this paper, we overview and compare the computing paradigms based on the emerging nanodevices towards ultra-low dissipation.展开更多
Low power consumption is a major issue in nowadays electronics systems. This trend is pushed by the development of data center related to cloud services and soon to the Internet of Things (IoT) deployment. Memories ...Low power consumption is a major issue in nowadays electronics systems. This trend is pushed by the development of data center related to cloud services and soon to the Internet of Things (IoT) deployment. Memories are one of the major contributors to power consumption. However, the development of emerging memory technologies paves the way to low-power design, through the partial replacement of the dynamic random access memory (DRAM) with the non-volatile stand-alone memory in servers or with the embedded or distributed emerging non-volatile memory in IoT objects. In the latter case, non-volatile flip-flops (NVFFs) seem a promising candidate to replace the retention latch. Indeed, IoT objects present long sleep time and NVFFs offer to save data in registers with zero power when the application is idle. This paper gives an overview of NVFF architecture flavors for various emerging memory technologies.展开更多
Interpretation of quantitative results of nerve fiber layer (NFL) thickness based on scanning laser polarimetry (GDx-NFA) can be quite challenging especially in glaucoma suspects. Purpose: Authors studied NFL paramete...Interpretation of quantitative results of nerve fiber layer (NFL) thickness based on scanning laser polarimetry (GDx-NFA) can be quite challenging especially in glaucoma suspects. Purpose: Authors studied NFL parameters obtained from GDx-NFA in glaucoma suspects and compared them with those of patients with glaucoma Methods: Eighty six glaucoma suspects based展开更多
Frequency doubling perimetry (FDP) may idendtify glaucoma at a relatively early stage even before conventional perimetry does. Scanning laser polarimetry (GDx) has shown to differentiate nerve fiber layer thickness (N...Frequency doubling perimetry (FDP) may idendtify glaucoma at a relatively early stage even before conventional perimetry does. Scanning laser polarimetry (GDx) has shown to differentiate nerve fiber layer thickness (NFLT) between glaucomatous展开更多
文摘Traditional digital processing approaches are based on semiconductor transistors, which suffer from high power consumption, aggravating with technology node scaling. To solve definitively this problem, a number of emerging non-volatile nanodevices are under intense investigations. Meanwhile, novel computing circuits are invented to dig the full potential of the nanodevices. The combination of non-volatile nanodevices with suitable computing paradigms have many merits compared with the complementary metal-oxide-semiconductor transistor (CMOS) technology based structures, such as zero standby power, ultra-high density, non-volatility, and acceptable access speed. In this paper, we overview and compare the computing paradigms based on the emerging nanodevices towards ultra-low dissipation.
基金supported by the ANR project DIPMEM under Grant No.ANR-12-NANO-0010-04
文摘Low power consumption is a major issue in nowadays electronics systems. This trend is pushed by the development of data center related to cloud services and soon to the Internet of Things (IoT) deployment. Memories are one of the major contributors to power consumption. However, the development of emerging memory technologies paves the way to low-power design, through the partial replacement of the dynamic random access memory (DRAM) with the non-volatile stand-alone memory in servers or with the embedded or distributed emerging non-volatile memory in IoT objects. In the latter case, non-volatile flip-flops (NVFFs) seem a promising candidate to replace the retention latch. Indeed, IoT objects present long sleep time and NVFFs offer to save data in registers with zero power when the application is idle. This paper gives an overview of NVFF architecture flavors for various emerging memory technologies.
文摘Interpretation of quantitative results of nerve fiber layer (NFL) thickness based on scanning laser polarimetry (GDx-NFA) can be quite challenging especially in glaucoma suspects. Purpose: Authors studied NFL parameters obtained from GDx-NFA in glaucoma suspects and compared them with those of patients with glaucoma Methods: Eighty six glaucoma suspects based
文摘Frequency doubling perimetry (FDP) may idendtify glaucoma at a relatively early stage even before conventional perimetry does. Scanning laser polarimetry (GDx) has shown to differentiate nerve fiber layer thickness (NFLT) between glaucomatous