Highly Scalable Embedded Flash Memory With Deep Trench Isolation and Novel Buried Bitline Integration for the 90-nm Node and Beyond

In this paper, we embedded a Flash memory cell with 90-nm ground-rules in a high-performance CMOS logic process. A novel deep trench isolation (DTI) module enables an isolated p-well (IPW) bias scheme, leading to Flash with uniform channel program/erase by Fowler-Nordheim tunneling without gate induced drain leakage, a key feature for low-power portable electronics. The IPW concept leads to a compact cell design and a highly scalable high-voltage periphery through the narrow intrawell and interwell isolation spaces. The memory arrays are defined by DTI of each bitline (BL) from its neighboring BLs. We additionally present a buried BL (BBL) concept that links the source contacts of each individual BL via the IPW; thus, effectively eliminating one metal line per BL and reducing overall cell size. A conservative cell size shrink of about 40% can be achieved for a uniform channel program/erase-Flash cell with deep trench and BBL compared to a conventional 21F²cell.     

A New Connection Admission Control for Spotbeam Handover in LEO Satellite Networks

Frequent spotbeam handovers in low earth orbit (LEO) satellite networks require a technique to decrease the handover blocking probabilities. A large variety of schemes have been proposed to achieve this goal in terrestrial mobile cellular networks. Most of them focus on the notion of prioritized channel allocation algorithms. However, these schemes cannot provide the connection-level quality of service (QoS) guarantees. Due to the scarcity of resources in LEO satellite networks, a connection admission control (CAC) technique becomes important to achieve this connection-level QoS for the spotbeam handovers. In this paper, a geographical connection admission control (GCAC) algorithm is introduced, which estimates the future handover blocking performance of a new call attempt based on the user location database, in order to decrease the handover blocking. Also, for its channel allocation scheme, an adaptive dynamic channel allocation (ADCA) scheme is introduced. By simulation, it is shown that the proposed GCAC with ADCA scheme guarantees the handover blocking probability to a predefined target level of QoS. Since GCAC algorithm utilizes the user location information, performance evaluation indicates that the quality of service (QoS) is also guaranteed in the non-uniform traffic pattern.     

Simulation and measurement: Feasibility study of Tactile Internet applications for mmWave virtual reality

Numerous wearable technology companies have recently developed several head‐mounted display (HMD) products for virtual reality (VR) services. 5G wireless networks aim at providing high‐quality 3D multimedia services such as VR, augmented reality, and mixed reality. In this study, we examine the application of millimeter‐wave (mmWave) technology to realize low‐latency wireless communication between an HMD and its content server. However, the propagation characteristics of mmWave present several challenges such as the deafness, blockage, and beam alignment problems, and interference among content servers. In this study, we focus on an environment that provides VR services in the mmWave band and introduce existing techniques for addressing such challenges. In addition, we employ a commercialized IEEE 802.11ad VR dongle to measure the actual data rate of an mmWave VR application and identify the degree to which the performance deteriorates when the above problems occur. Finally, we verify the feasibility of the proposed solutions through a simulation of several VR scenarios in the mmWave band.