Abstract
Recently, nonvolatile systems with nonvolatile flip-flops (NVFFs) have gained prominence for their energy efficiency in energy-harvesting devices and battery-operated Internet of Things applications. They are normally-off instantly-on, and thus, can save energy effectively owing to their zero standby power consumption. An NVFF stores the computing state in nonvolatile memories (NVMs) when the power is off. A ferroelectric field-effect transistor (FeFET) is one of the most promising NVMs owing to its high $\text{I}_{\mathrm {on}}/\text{I}_{\mathrm {off}}$ ratio and low write power. Three FeFET-based NVFFs (previous FeFET-out NVFF-1/-2 and FeFET-in NVFF) were recently proposed to improve the area, power, and speed; however, they still have their own problems. Previous FeFET-out NVFF-1 has large area overhead and previous FeFET-out NVFF-2 does not properly perform restore operation. Previous FeFET-in NVFF has a long clock-to-Q delay and high operating energy. This paper introduces two novel FeFET-based NVFFs (proposed FeFET-out and -in NVFFs). Proposed FeFET-out NVFF reduces the large area overhead of previous FeFET-out NVFF-1 and corrects the malfunction in the restore operation of previous FeFET-out NVFF-2. Proposed FeFET-in NVFF achieves a better clock-to-Q delay, operating energy, and area than the previous FeFET-in NVFF. Monte Carlo simulations based on an industry-compatible 10-nm FinFET model are performed for a comparative analysis. Proposed FeFET-out NVFF achieves 17.6% smaller area with slightly higher (6.3%) operating energy and only 0.8% slower clock-to-Q delay than previous FeFET-out NVFF-1. Proposed FeFET-in NVFF achieves 18.9% shorter clock-to-Q and 3.0% smaller operating energy with 8.7% smaller area than the previous FeFET-in NVFF.
Highlights
In recent years, Internet of Things (IoT) applications have been extensively adopted for many electronic devices
PROPOSED field-effect transistor (FeFET)-BASED NONVOLATILE FLIP-FLOPS we propose two FeFET-based nonvolatile flip-flops (NVFFs) having FeFET-out and FeFET-in structures employing the conventional transmission gate flip-flops (TGFFs) as the base structure
The proposed FeFET-in NVFF achieves a clock-to-Q delay of 59.82 ps (+4.5% compared to the TGFF), which is reduced by 18.9% versus the previous FeFET-in NVFF, and it has four gate capacitances (FeFET) in the critical path
Summary
Internet of Things (IoT) applications have been extensively adopted for many electronic devices. The other read circuit is composed of a minimum-sized pMOS (MP1), a large-sized n-FeFET (FN1), and an nMOS (MN1), as shown in Fig. 4(d) [26] In this case, if FN1 is in the HRS, node OUT is pulled up to VDD. Because a ‘‘controlled’’ backup operation needs dynamic VDD, the backup signal is embedded in the supply voltage line to increase VDD beyond VC, which provides sufficient VGS to switch the polarization states of the FE layers. Because such dynamic VDD has already been extensively used in many digital circuits, NVFFs can reuse a VDD modulation unit without introducing other overheads [25], [26]. We review three latest FeFET-based NVFFs in [25], [26] in terms of their structures, overall operations, and issues
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
