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1. Influence of three-dimensionality on wake synchronization of oscillatory cylinder

Author

Kim, Youngjae, Godavarthi, Vedasri, Rolandi, Laura Victoria, Klamo, Joseph T., and Taira, Kunihiko

Subjects
Physics - Fluid Dynamics
Abstract

We investigate the effect of three-dimensionality on the synchronization characteristics of the wake behind an oscillating circular cylinder at Re = 300. Cylinder oscillations in rotation, transverse translation, and streamwise translation are considered. We utilize phase-reduction analysis, which quantifies the phase-sensitivity function of periodic flows, to examine the synchronization properties. Here, we present an ensemble-based framework for phase-reduction analysis to handle three-dimensional wakes that are not perfectly time-periodic. Based on the phase-sensitivity functions, synchronizability to three types of cylinder oscillations is evaluated. In spite of similar trends, we find that phase-sensitivity functions involving three-dimensional wakes are lower in magnitude compared to those of two-dimensional wakes, which leads to narrower conditions for synchronization to weak cylinder oscillations. We unveil that the difference between the phase-sensitivity functions of two- and three-dimensional flows is strongly correlated to the amplitude variation of the three-dimensional flow by the cylinder motions. This finding reveals that the cylinder motion modifies the three-dimensionality of the wake as well as the phase of vortex shedding, which leads to reduced phase modulation. The synchronization conditions of three-dimensional wakes, predicted by phase-reduction analysis, agree with the identification by parametric studies using direct numerical simulations for forced oscillations with small amplitudes. This study presents the potential capability of phase-reduction to study synchronization characteristics of complex flows., Comment: 21 pages, 15 figures

Published
2024

2. A Host-SSD Collaborative Write Accelerator for LSM-Tree-Based Key-Value Stores

Author

Kim, KiHwan, Chung, Hyunsun, Ahn, Seonghoon, Park, Junhyeok, Jamil, Safdar, Byun, Hongsu, Lee, Myungcheol, Choi, Jinchun, and Kim, Youngjae

Subjects
Computer Science - Hardware Architecture
Abstract

Log-Structured Merge (LSM) tree-based Key-Value Stores (KVSs) are widely adopted for their high performance in write-intensive environments, but they often face performance degradation due to write stalls during compaction. Prior solutions, such as regulating I/O traffic or using multiple compaction threads, can cause unexpected drops in throughput or increase host CPU usage, while hardware-based approaches using FPGA, GPU, and DPU aimed at reducing compaction duration introduce additional hardware costs. In this study, we propose KVACCEL, a novel hardware-software co-design framework that eliminates write stalls by leveraging a dual-interface SSD. KVACCEL allocates logical NAND flash space to support both block and key-value interfaces, using the key-value interface as a temporary write buffer during write stalls. This strategy significantly reduces write stalls, optimizes resource usage, and ensures consistency between the host and device by implementing an in-device LSM-based write buffer with an iterator-based range scan mechanism. Our extensive evaluation shows that for write-intensive workloads, KVACCEL outperforms ADOC by up to 1.17x in terms of throughput and performance-to-CPU-utilization efficiency. For mixed read-write workloads, both demonstrate comparable performance., Comment: 11 pages, 14 figures

Published
2024

3. Topological beaming of light: Proof-of-concept experiment

Author

Choi, Yu Sung, Lee, Ki Young, An, Soo-Chan, Jang, Minchul, Kim, Youngjae, Shin, Seung Han, and Yoon, Jae Woong

Subjects
Physics - Optics
Abstract

Beam shaping in nanophotonic systems remains a challenge due to the reliance on complex heuristic optimization procedures. In this work, we experimentally demonstrate a novel approach to topological beam shaping using Jackiw-Rebbi states in metasurfaces. By fabricating thin-film dielectric structures with engineered Dirac-mass distributions, we create domain walls that allow precise control over beam profiles. We observe the emergence of Jackiw-Rebbi states and confirm their localized characteristics. Notably, we achieve a flat-top beam profile by carefully tailoring the Dirac mass distribution, highlighting the potential of this method for customized beam shaping. This experimental realization establishes our approach as a new mechanism for beam control, rooted in topological physics, and offers an efficient strategy for nanophotonic design.

Published
2024

4. Audio-Based Linguistic Feature Extraction for Enhancing Multi-lingual and Low-Resource Text-to-Speech

Author

Kim, Youngjae, Jeon, Yejin, and Lee, Gary Geunbae

Subjects
Computer Science - Sound, Electrical Engineering and Systems Science - Audio and Speech Processing
Abstract

The difficulty of acquiring abundant, high-quality data, especially in multi-lingual contexts, has sparked interest in addressing low-resource scenarios. Moreover, current literature rely on fixed expressions from language IDs, which results in the inadequate learning of language representations, and the failure to generate speech in unseen languages. To address these challenges, we propose a novel method that directly extracts linguistic features from audio input while effectively filtering out miscellaneous acoustic information including speaker-specific attributes like timbre. Subjective and objective evaluations affirm the effectiveness of our approach for multi-lingual text-to-speech, and highlight its superiority in low-resource transfer learning for previously unseen language., Comment: EMNLP 2024 Findings

Published
2024

5. DeepVM: Integrating Spot and On-Demand VMs for Cost-Efficient Deep Learning Clusters in the Cloud

Author

Kim, Yoochan, Kim, Kihyun, Cho, Yonghyeon, Kim, Jinwoo, Khan, Awais, Kang, Ki-Dong, An, Baik-Song, Cha, Myung-Hoon, Kim, Hong-Yeon, and Kim, Youngjae

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Distributed Deep Learning (DDL), as a paradigm, dictates the use of GPU-based clusters as the optimal infrastructure for training large-scale Deep Neural Networks (DNNs). However, the high cost of such resources makes them inaccessible to many users. Public cloud services, particularly Spot Virtual Machines (VMs), offer a cost-effective alternative, but their unpredictable availability poses a significant challenge to the crucial checkpointing process in DDL. To address this, we introduce DeepVM, a novel solution that recommends cost-effective cluster configurations by intelligently balancing the use of Spot and On-Demand VMs. DeepVM leverages a four-stage process that analyzes instance performance using the FLOPP (FLoating-point Operations Per Price) metric, performs architecture-level analysis with linear programming, and identifies the optimal configuration for the user-specific needs. Extensive simulations and real-world deployments in the AWS environment demonstrate that DeepVM consistently outperforms other policies, reducing training costs and overall makespan. By enabling cost-effective checkpointing with Spot VMs, DeepVM opens up DDL to a wider range of users and facilitates a more efficient training of complex DNNs., Comment: 14 pages, 8 figures

Published
2024

6. Pseudospins revealed through the giant dynamical Franz-Keldysh effect in massless Dirac materials

Author

Kim, Youngjae

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Physics - Optics
Abstract

The dynamical Franz-Keldysh effect, indicative of the transient light-matter interaction regime between quantum and classical realms, is widely recognized as an essential signature in wide bandgap condensed matter systems such as dielectrics. In this study, we applied the time-resolved transient absorption spectroscopy to investigate ultrafast optical responses in graphene, a zero-bandgap system. We observed in the gate-tuned graphene that the massless Dirac materials notably enhance intraband light-driven transitions, significantly leading to the giant dynamical Franz-Keldysh effect compared to the massive Dirac materials, a wide bandgap system. In addition, employing the angle-resolved spectroscopy, it is found that the unique polarimetry orientation, i.e., perpendicular polarizations for the pump and the probe, further pronounces the optical spectra to exhibit the complete fishbone structure, reflecting the quantum pseudospin nature of Dirac cones. Our findings expand the establishment of emergent transient spectroscopy frameworks into not only zero-bandgap systems but also pseudospin-mediated quantum phenomena, moving beyond dielectrics., Comment: 7 pages, 5 figures

Published
2024

8. On stable wrapper-based parameter selection method for efficient ANN-based data-driven modeling of turbulent flows

Author

Yun, Hyeongeun, Choi, Yongcheol, Kim, Youngjae, and Kang, Seongwon

Subjects
Physics - Fluid Dynamics, Computer Science - Artificial Intelligence, Physics - Computational Physics
Abstract

To model complex turbulent flow and heat transfer phenomena, this study aims to analyze and develop a reduced modeling approach based on artificial neural network (ANN) and wrapper methods. This approach has an advantage over other methods such as the correlation-based filter method in terms of removing redundant or irrelevant parameters even under non-linearity among them. As a downside, the overfitting and randomness of ANN training may produce inconsistent subsets over selection trials especially in a higher physical dimension. This study analyzes a few existing ANN-based wrapper methods and develops a revised one based on the gradient-based subset selection indices to minimize the loss in the total derivative or the directional consistency at each elimination step. To examine parameter reduction performance and consistency-over-trials, we apply these methods to a manufactured subset selection problem, modeling of the bubble size in a turbulent bubbly flow, and modeling of the spatially varying turbulent Prandtl number in a duct flow. It is found that the gradient-based subset selection to minimize the total derivative loss results in improved consistency-over-trials compared to the other ANN-based wrapper methods, while removing unnecessary parameters successfully. For the reduced turbulent Prandtl number model, the gradient-based subset selection improves the prediction in the validation case over the other methods. Also, the reduced parameter subsets show a slight increase in the training speed compared to the others., Comment: 24 pages, 26 figures

Published
2023

9. An Analytical Model-based Capacity Planning Approach for Building CSD-based Storage Systems

Author

Byun, Hongsu, Jamil, Safdar, Han, Jungwook, Park, Sungyong, Lee, Myungcheol, Kim, Changsoo, Choi, Beongjun, and Kim, Youngjae

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

The data movement in large-scale computing facilities (from compute nodes to data nodes) is categorized as one of the major contributors to high cost and energy utilization. To tackle it, in-storage processing (ISP) within storage devices, such as Solid-State Drives (SSDs), has been explored actively. The introduction of computational storage drives (CSDs) enabled ISP within the same form factor as regular SSDs and made it easy to replace SSDs within traditional compute nodes. With CSDs, host systems can offload various operations such as search, filter, and count. However, commercialized CSDs have different hardware resources and performance characteristics. Thus, it requires careful consideration of hardware, performance, and workload characteristics for building a CSD-based storage system within a compute node. Therefore, storage architects are hesitant to build a storage system based on CSDs as there are no tools to determine the benefits of CSD-based compute nodes to meet the performance requirements compared to traditional nodes based on SSDs. In this work, we proposed an analytical model-based storage capacity planner called CSDPlan for system architects to build performance-effective CSD-based compute nodes. Our model takes into account the performance characteristics of the host system, targeted workloads, and hardware and performance characteristics of CSDs to be deployed and provides optimal configuration based on the number of CSDs for a compute node. Furthermore, CSDPlan estimates and reduces the total cost of ownership (TCO) for building a CSD-based compute node. To evaluate the efficacy of CSDPlan, we selected two commercially available CSDs and 4 representative big data analysis workloads.

Published
2023
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10. Aster-dependent nonvesicular transport facilitates dietary cholesterol uptake

Author

Ferrari, Alessandra, Whang, Emily, Xiao, Xu, Kennelly, John P, Romartinez-Alonso, Beatriz, Mack, Julia J, Weston, Thomas, Chen, Kai, Kim, Youngjae, Tol, Marcus J, Bideyan, Lara, Nguyen, Alexander, Gao, Yajing, Cui, Liujuan, Bedard, Alexander H, Sandhu, Jaspreet, Lee, Stephen D, Fairall, Louise, Williams, Kevin J, Song, Wenxin, Munguia, Priscilla, Russell, Robert A, Martin, Martin G, Jung, Michael E, Jiang, Haibo, Schwabe, John WR, Young, Stephen G, and Tontonoz, Peter

Subjects
Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Digestive Diseases, Nutrition, Animals, Mice, Biological Transport, Cholesterol, Dietary, Intestinal Absorption, Membrane Transport Proteins, Mice, Inbred C57BL, Enterocytes, Liver X Receptors, Humans, Jejunum, Mice, Knockout, General Science & Technology
Abstract

Intestinal absorption is an important contributor to systemic cholesterol homeostasis. Niemann-Pick C1 Like 1 (NPC1L1) assists in the initial step of dietary cholesterol uptake, but how cholesterol moves downstream of NPC1L1 is unknown. We show that Aster-B and Aster-C are critical for nonvesicular cholesterol movement in enterocytes. Loss of NPC1L1 diminishes accessible plasma membrane (PM) cholesterol and abolishes Aster recruitment to the intestinal brush border. Enterocytes lacking Asters accumulate PM cholesterol and show endoplasmic reticulum cholesterol depletion. Aster-deficient mice have impaired cholesterol absorption and are protected against diet-induced hypercholesterolemia. Finally, the Aster pathway can be targeted with a small-molecule inhibitor to manipulate cholesterol uptake. These findings identify the Aster pathway as a physiologically important and pharmacologically tractable node in dietary lipid absorption.

Published
2023

12. Attosecond Transient Absorption Spectroscopy of Strongly Correlated Mott Insulators: Signature of the Creation and Annihilation of Double Occupancy

Author

Kim, Youngjae

Subjects
Condensed Matter - Strongly Correlated Electrons, Physics - Optics
Abstract

We applied the time-resolved attosecond transient absorption spectroscopy to systematically investigate ultrafast optical responses of condensed matter systems. Under an intense pump pulse, absorption spectra indicate that the non-interacting electrons of band insulators produce a field-induced redshift, known as the dynamical Franz-Keldysh effect, as commonly expected. In contrast to the band insulators, in Mott insulators, unconventional spectra are observed which do not fully reflect the dynamical Franz-Keldysh effect. While it still exhibits the fishbone-like structures mimicking the dynamical Franz-Keldysh effect, the spectra show a negative difference absorption below the band edge, rendering a blueshift. In addition, the decomposed difference absorption reveals the creation and the annihilation of double occupancy mainly contribute to the negative signal, implying that the unconventional spectra are purely driven by the electron-correlations. These demonstrations of unconventional responses would guide us to the correlation-embedded attosecond electron dynamics in condensed matter systems., Comment: 7 pages, 8 figures

Published
2023
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13. Gate-tunable quantum pathways of high harmonic generation in graphene

Author

Cha, Soonyoung, Kim, Minjeong, Kim, Youngjae, Choi, Shinyoung, Kang, Sejong, Kim, Hoon, Yoon, Sangho, Moon, Gunho, Kim, Taeho, Lee, Ye Won, Cho, Gil Young, Park, Moon Jeong, Kim, Cheol-Joo, Kim, B. J., Lee, JaeDong, Jo, Moon-Ho, and Kim, Jonghwan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics
Abstract

Under strong laser fields, electrons in solids radiate high-harmonic fields by travelling through quantum pathways in Bloch bands in the sub-laser-cycle timescales. Understanding these pathways in the momentum space through the high-harmonic radiation can enable an all-optical ultrafast probe to observe coherent lightwave-driven processes and measure electronic structures as recently demonstrated for semiconductors. However, such demonstration has been largely limited for semimetals because the absence of the bandgap hinders an experimental characterization of the exact pathways. In this study, by combining electrostatic control of chemical potentials with HHG measurement, we resolve quantum pathways of massless Dirac fermions in graphene under strong laser fields. Electrical modulation of HHG reveals quantum interference between the multi-photon interband excitation channels. As the light-matter interaction deviates beyond the perturbative regime, elliptically polarized laser fields efficiently drive massless Dirac fermions via an intricate coupling between the interband and intraband transitions, which is corroborated by our theoretical calculations. Our findings pave the way for strong-laser-field tomography of Dirac electrons in various quantum semimetals and their ultrafast electronics with a gate control., Comment: 33 pages, 4 figures, Soonyoung Cha and Minjeong Kim contributed equally to this work, To whom correspondence should be addressed: jonghwankim@postech

Published
2022
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14. Defect Passivation of 2D Semiconductors by Fixating Chemisorbed Oxygen Molecules via h-BN Encapsulations

Author

Jung, Jin-Woo, Choi, Hyeon-Seo, Lee, Young-Jun, Kim, Youngjae, Taniguchi, Takashi, Watanabe, Kenji, Choi, Min-Yeong, Jang, Jae Hyuck, Chung, Hee-Suk, Kim, Dohun, Kim, Youngwook, and Cho, Chang-Hee

Subjects
Physics - Applied Physics
Abstract

Hexagonal boron nitride (h-BN) is a key ingredient for various two-dimensional (2D) van der Waals heterostructure devices, but the exact role of h-BN encapsulation in relation to the internal defects of 2D semiconductors remains unclear. Here, we report that h-BN encapsulation greatly removes the defect-related gap states by stabilizing the chemisorbed oxygen molecules onto the defects of monolayer WS2 crystals. Electron energy loss spectroscopy (EELS) combined with theoretical analysis clearly confirms that the oxygen molecules are chemisorbed onto the defects of WS2 crystals and are fixated by h-BN encapsulation, with excluding a possibility of oxygen molecules trapped in bubbles or wrinkles formed at the interface between WS2 and h-BN. Optical spectroscopic studies show that h-BN encapsulation prevents the desorption of oxygen molecules over various excitation and ambient conditions, resulting in a greatly lowered and stabilized free electron density in monolayer WS2 crystals. This suppresses the exciton annihilation processes by two orders of magnitude compared to that of bare WS2. Furthermore, the valley polarization becomes robust against the various excitation and ambient conditions in the h-BN encapsulated WS2 crystals.

Published
2022
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16. A Probabilistic Machine Learning Approach to Scheduling Parallel Loops with Bayesian Optimization

Author

Kim, Kyurae, Kim, Youngjae, and Park, Sungyong

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Performance, D.4.9, D.4.8
Abstract

This paper proposes Bayesian optimization augmented factoring self-scheduling (BO FSS), a new parallel loop scheduling strategy. BO FSS is an automatic tuning variant of the factoring self-scheduling (FSS) algorithm and is based on Bayesian optimization (BO), a black-box optimization algorithm. Its core idea is to automatically tune the internal parameter of FSS by solving an optimization problem using BO. The tuning procedure only requires online execution time measurement of the target loop. In order to apply BO, we model the execution time using two Gaussian process (GP) probabilistic machine learning models. Notably, we propose a locality-aware GP model, which assumes that the temporal locality effect resembles an exponentially decreasing function. By accurately modeling the temporal locality effect, our locality-aware GP model accelerates the convergence of BO. We implemented BO FSS on the GCC implementation of the OpenMP standard and evaluated its performance against other scheduling algorithms. Also, to quantify our method's performance variation on different workloads, or workload-robustness in our terms, we measure the minimax regret. According to the minimax regret, BO FSS shows more consistent performance than other algorithms. Within the considered workloads, BO FSS improves the execution time of FSS by as much as 22% and 5% on average., Comment: Part of TPDS Special Section on Parallel and Distributed Computing Techniques for AI, ML, and DL

Published
2022
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21. A Policy-based Versioning SSD with Intel SGX

Author

Ahn, Jinwoo, Lee, Seungjin, Lee, Jinhoon, Ko, Youngwoo, Lee, Junghee, and Kim, Youngjae

Subjects
Computer Science - Cryptography and Security
Abstract

Privileged malware neutralizes software-based versioning systems and destroys data. To counter this threat, a versioning solid-state drive (SSD) that performs versioning inside the SSD has been studied. An SSD is a suitable candidate for data versioning because it can preserve previous versions without additional copying, and provide high security with a very small trusted computing base (TCB). However, the versioning SSDs studied so far commonly use a full disk versioning method that preserves all file versions in a batch. This paper demonstrates that SSDs, which provide full disk versioning, can be exposed to data tampering attacks when the retention time of data is less than the malware's dwell time. To deal with this threat, we propose SGX-SSD, a policy-based per-file versioning SSD to keep a deeper history for only the important files of users. However, since the SSD isn't aware of a file semantic, and the versioning policy information should be securely received from the untrusted host computer, implementing the per-file versioning in SSD is a huge challenge. To solve this problem, SGX-SSD utilizes the Intel SGX and has a secure host interface to securely receive policy information (configuration values) from the user. Also, to solve the file semantic unawareness problem of the SSD, a piggyback module is designed to give a file hint at the host layer, and an algorithm for selective versioning based on the policy is implemented in the SSD. To prove our system, we prototyped SGX-SSD the Jasmine OpenSSD platform in Linux environment. In the experimental evaluation, we proved that SGX-SSD provides strong security with little additional overhead for selective per-file versioning., Comment: 14 pages

Published
2021

25. Production of High-Purity Mg Metal from Various MgO Resources Through a Novel Electrolytic Process Using a Cu Cathode and Vacuum Distillation

Author

Jeoung, Hyeong-Jun, Lee, Tae-Hyuk, Kim, Youngjae, Lee, Jin-Young, Kim, Young Min, Okabe, Toru H., Yi, Kyung-Woo, Kang, Jungshin, Ouchi, Takanari, editor, Forsberg, Kerstin, editor, Azimi, Gisele, editor, Alam, Shafiq, editor, Neelameggham, Neale R., editor, Kim, Hojong, editor, Baba, Alafara Abdullahi, editor, Peng, Hong, editor, and Karamalidis, Athanasios, editor

Published
2023
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26. Longitudinal Associations between Vocational Identity Process and Career Goals

Author

Lee, Yuyoung, Kim, Youngjae, Im, Sojeong, Lee, Eunbi, and Yang, Eunjoo

Abstract

Vocational identity develops through the interplay between process and content dimensions. A three-wave longitudinal study investigated how identity process dimensions (in-breadth exploration, in-depth exploration, commitment making, identification with commitment, self-doubt, flexibility) and content dimensions represented by career goals (intrinsic goals, extrinsic goals) are interconnected across time. Participants were 327 full-time college students in South Korea at Time 1, 253 at Time 2, and 227 at Time 3. They rated values associated with their current career goal and completed the Vocational Identity Status Assessment 3 times with a 6-month interval. The autoregressive cross-lagged path analysis found positive reciprocal associations between intrinsic career goals and identification with commitment. Furthermore, intrinsic career goals positively predicted in-depth exploration, and self-doubt negatively predicted intrinsic career goals. These findings support the reciprocal relationships between vocational identity process and career goals in general, and between intrinsic career goals and the commitment dimension of identity more specifically.

Published
2022
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27. A Generic Framework For Capturing Reliability in Cyber Physical Systems

Author

Ali, Nazakat, Hussain, Manzoor, Kim, Youngjae, and Hong, Jang-Eui

Subjects
Computer Science - Software Engineering
Abstract

Cyber Physical Systems solve complex problems through their tight integration between the physical and computational components. Therefore, the reliability of a complex system is the most critical requirement for the cyber physical system because an unreliable system often leads to service disruption, property dam-age, financial loses and sometimes lead to fatality. In order to develop more reliable CPS, this paper proposes a generic framework for reliability modeling and analysis for our ongoing work on cyber physical systems.This paper, at first defines an architecture for general CPS which is comprised of three layers; environment layer, communication layer, and computational layer. Secondly, we formalize a reliability model for the architectural components, and then propose a framework for the reliability of CPS with the consideration of how to capture the reliability. Based on the research method, we demonstrate the proposed frame-work with an illustrative example by using different reliability values from offshore and onshore reliability data library. We confirmed that the reliability model covers almost all possible reliabilities required to general cyber-physical systems.

Published
2020

28. Optimizing Placement of Heap Memory Objects in Energy-Constrained Hybrid Memory Systems

Author

Kim, Taeuk, Jamil, Safdar, Park, Joongeon, and Kim, Youngjae

Subjects
Computer Science - Hardware Architecture, Computer Science - Emerging Technologies, Computer Science - Operating Systems
Abstract

Main memory (DRAM) significantly impacts the power and energy utilization of the overall server system. Non-Volatile Memory (NVM) devices, such as Phase Change Memory and Spin-Transfer Torque RAM, are suitable candidates for main memory to reduce energy consumption. But unlike DRAM, NVMs access latencies are higher than DRAM and NVM writes are more energy sensitive than DRAM write operations. Thus, Hybrid Main Memory Systems (HMMS) employing DRAM and NVM have been proposed to reduce the overall energy depletion of main memory while optimizing the performance of NVM. This paper proposes eMap, an optimal heap memory object placement planner in HMMS. eMap considers the object-level access patterns and energy consumption at the application level and provides an ideal placement strategy for each object to augment performance and energy utilization. eMap is equipped with two modules, eMPlan and eMDyn. Specifically, eMPlan is a static placement planner which provides one time placement policies for memory object to meet the energy budget while eMDyn is a runtime placement planner to consider the change in energy limiting constraint during the runtime and shuffles the memory objects by taking into account the access patterns as well as the migration cost in terms of energy and performance. The evaluation shows that our proposed solution satisfies both the energy limiting constraint and the performance. We compare our methodology with the state-of-the-art memory object classification and allocation (MOCA) framework. Our extensive evaluation shows that our proposed solution, eMPlan meets the energy constraint with 4.17 times less costly and reducing the energy consumption up to 14% with the same performance. eMDyn also satisfies the performance and energy requirement while considering the migration cost in terms of time and energy.

Published
2020

29. SGX-SSD: A Policy-based Versioning SSD with Intel SGX

Author

Ahn, Jinwoo, Lee, Seungjin, Lee, Jinhoon, Ko, Yungwoo, Min, Donghyun, Lee, Junghee, and Kim, Youngjae

Subjects
Computer Science - Cryptography and Security, E.5
Abstract

This paper demonstrates that SSDs, which perform device-level versioning, can be exposed to data tampering attacks when the retention time of data is less than the malware's dwell time. To deal with that threat, we propose SGX-SSD, a SGX-based versioning SSD which selectively preserves file history based on the given policy. The proposed system adopts Intel SGX to implement the version policy management system that is safe from high-privileged malware. Based on the policy, only the necessary data is selectively preserved in SSD that prevents files with less priority from wasting space and also ensures the integrity of important files., Comment: 7 pages, 4 figures

Published
2020

31. Selective Aster inhibitors distinguish vesicular and nonvesicular sterol transport mechanisms

Author

Xiao, Xu, Kim, Youngjae, Romartinez-Alonso, Beatriz, Sirvydis, Kristupas, Ory, Daniel S, Schwabe, John WR, Jung, Michael E, and Tontonoz, Peter

Subjects
Biochemistry and Cell Biology, Biological Sciences, Biotechnology, Underpinning research, 5.1 Pharmaceuticals, 1.1 Normal biological development and functioning, Development of treatments and therapeutic interventions, Generic health relevance, Androstenes, Animals, Biological Transport, CHO Cells, Carrier Proteins, Cell Membrane, Cholesterol, Cholesterol, LDL, Cricetulus, Endoplasmic Reticulum, Humans, Hydroxycholesterols, Intracellular Signaling Peptides and Proteins, Membrane Glycoproteins, Membrane Proteins, Niemann-Pick C1 Protein, Sterol Regulatory Element Binding Protein 2, Sterols, cholesterol, lipid transport, lipid metabolism
Abstract

The Aster proteins (encoded by the Gramd1a-c genes) contain a ligand-binding fold structurally similar to a START domain and mediate nonvesicular plasma membrane (PM) to endoplasmic reticulum (ER) cholesterol transport. In an effort to develop small molecule modulators of Asters, we identified 20α-hydroxycholesterol (HC) and U18666A as lead compounds. Unfortunately, both 20α-HC and U18666A target other sterol homeostatic proteins, limiting their utility. 20α-HC inhibits sterol regulatory element-binding protein 2 (SREBP2) processing, and U18666A is an inhibitor of the vesicular trafficking protein Niemann-Pick C1 (NPC1). To develop potent and selective Aster inhibitors, we synthesized a series of compounds by modifying 20α-HC and U18666A. Among these, AI (Aster inhibitor)-1l, which has a longer side chain than 20α-HC, selectively bound to Aster-C. The crystal structure of Aster-C in complex with AI-1l suggests that sequence and flexibility differences in the loop that gates the binding cavity may account for the ligand specificity for Aster C. We further identified the U18666A analog AI-3d as a potent inhibitor of all three Aster proteins. AI-3d blocks the ability of Asters to bind and transfer cholesterol in vitro and in cells. Importantly, AI-3d also inhibits the movement of low-density lipoprotein (LDL) cholesterol to the ER, although AI-3d does not block NPC1. This finding positions the nonvesicular Aster pathway downstream of NPC1-dependent vesicular transport in the movement of LDL cholesterol to the ER. Selective Aster inhibitors represent useful chemical tools to distinguish vesicular and nonvesicular sterol transport mechanisms in mammalian cells.

Published
2021

33. KEY-SSD: Access-Control Drive to Protect Files from Ransomware Attacks

Author

Ahn, Jinwoo, Park, Donggyu, Lee, Chang-Gyu, Min, Donghyun, Lee, Junghee, Park, Sungyong, Chen, Qian, and Kim, Youngjae

Subjects
Computer Science - Cryptography and Security, Computer Science - Operating Systems
Abstract

Traditional techniques to prevent damage from ransomware attacks are to detect and block attacks by monitoring the known behaviors such as frequent name changes, recurring access to cryptographic libraries and exchange keys with remote servers. Unfortunately, intelligent ransomware can easily bypass these techniques. Another prevention technique is to recover from the backup copy when a file is infected with ransomware. However, the data backup technique requires extra storage space and can be removed with ransomware. In this paper, we propose to implement an access control mechanism on a disk drive, called a KEY-SSD disk drive. KEY-SSD is the data store and the last barrier to data protection. Unauthorized applications will not be able to read file data even if they bypass the file system defense, thus denying the block request without knowing the disk's registered block key and completely eliminating the possibility of the file becoming hostage to ransomware. We have prototyped KEY-SSD and validated the usefulness of KEY-SSD by demonstrating 1) selective block access control, 2) unauthorized data access blocking and 3) negligible performance overhead. Our comprehensive evaluation of KEY-SSD for various workloads show the KEY-SSD performance is hardly degraded due to OS lightweight key transmission and access control drive optimization. We also confirmed that KEY-SSD successfully protects the files in the actual ransomware sample., Comment: 12 pages, 20 figures

Published
2019

38. FT-LADS: Fault-Tolerant Object-Logging based Big Data Transfer System using Layout-Aware Data Scheduling

Author

Kasu, Preethika, Kim, Taeuk, Kim, Youngjae, Um, Jung-Ho, Park, Kyongseok, and Atchley, Scott

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Layout-Aware Data Scheduler (LADS) data transfer tool, identifies and addresses the issues that lead to congestion on the path of an end-to-end data transfer in the terabit network environments. It exploits the underlying storage layout at each endpoint to maximize throughput without negatively impacting the performance of shared storage resources for other users. LADS can avoid congested storage elements within the shared storage resource, improving input/output bandwidth, and hence the data transfer rates across the high speed networks. However, absence of FT (fault tolerance) support in LADS results in data re-transmission overhead along with the possible integrity issues upon errors. In this paper, we propose object based logging methods to avoid transmitting the objects which are successfully written to Parallel File System (PFS) at the sink end. Depending on the number of logger files created, for the whole dataset, we classified our fault tolerance mechanisms into three different categories: File logger, Transaction logger and Universal logger. Also, to address space overhead of these object based logging mechanisms, we have proposed different methods of populating logger files with the information of the completed objects. We have evaluated the data transfer performance and recovery time overhead of the proposed object based logging fault tolerant mechanisms on LADS data transfer tool. Our experimental results show that, LADS in conjunction with proposed object based fault tolerance mechanisms exhibit an overhead of less than 1% with respect to data transfer time and total recovery time overhead is around 10% of total data transfer time at any fault point., Comment: 35 pages,10 figures

Published
2018
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39. SCISPACE: A Scientific Collaboration Workspace for File Systems in Geo-Distributed HPC Data Centers

Author

Khan, Awais, Kim, Taeuk, Byun, Hyunki, Kim, Youngjae, Park, Sungyong, and Sim, Hyogi

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Future terabit networks are committed to dramatically improving big data motion between geographically dispersed HPC data centers.The scientific community takes advantage of the terabit networks such as DOE's ESnet and accelerates the trend to build a small world of collaboration between geospatial HPC data centers. It improves information and resource sharing for joint simulation and analysis between the HPC data centers. In this paper, we propose to build SCISPACE (Scientific Collaboration Workspace) for collaborative data centers. It provides a global view of information shared from multiple geo-distributed HPC data centers under a single workspace. SCISPACE supports native data-access to gain high-performance when data read or write is required in native data center namespace. It is accomplished by integrating a metadata export protocol. To optimize scientific collaborations across HPC data centers, SCISPACE implements search and discovery service. To evaluate, we configured two geo-distributed small-scale HPC data centers connected via high-speed Infiniband network, equipped with LustreFS. We show the feasibility of SCISPACE using real scientific datasets and applications. The evaluation results show average 36\% performance boost when the proposed native-data access is employed in collaborations., Comment: 8 pages including references

Published
2018

40. A Robust Fault-Tolerant and Scalable Cluster-wide Deduplication for Shared-Nothing Storage Systems

Author

Khan, Awais, Lee, Chang-Gyu, Hamandawana, Prince, Park, Sungyong, and Kim, Youngjae

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Deduplication has been largely employed in distributed storage systems to improve space efficiency. Traditional deduplication research ignores the design specifications of shared-nothing distributed storage systems such as no central metadata bottleneck, scalability, and storage rebalancing. Further, deduplication introduces transactional changes, which are prone to errors in the event of a system failure, resulting in inconsistencies in data and deduplication metadata. In this paper, we propose a robust, fault-tolerant and scalable cluster-wide deduplication that can eliminate duplicate copies across the cluster. We design a distributed deduplication metadata shard which guarantees performance scalability while preserving the design constraints of shared- nothing storage systems. The placement of chunks and deduplication metadata is made cluster-wide based on the content fingerprint of chunks. To ensure transactional consistency and garbage identification, we employ a flag-based asynchronous consistency mechanism. We implement the proposed deduplication on Ceph. The evaluation shows high disk-space savings with minimal performance degradation as well as high robustness in the event of sudden server failure., Comment: 6 Pages including references

Published
2018

43. An Analytical Model-based Capacity Planning Approach for Building CSD-based Storage Systems.

Author

Byun, Hongsu, Jamil, Safdar, Han, Jungwook, Park, Sungyong, Lee, Myungcheol, Kim, Changsoo, Choi, Beongjun, and Kim, Youngjae

Subjects
TOTAL cost of ownership, WAREHOUSES, ENERGY consumption, CONSTRUCTION planning, CAPACITY requirements planning
Abstract

The data movement in large-scale computing facilities (from compute nodes to data nodes) is categorized as one of the major contributors to high cost and energy utilization. To tackle it, in-storage processing (ISP) within storage devices, such as Solid-State Drives (SSDs), has been explored actively. The introduction of computational storage drives (CSDs) enabled ISP within the same form factor as regular SSDs and made it easy to replace SSDs within traditional compute nodes. With CSDs, host systems can offload various operations such as search, filter, and count. However, commercialized CSDs have different hardware resources and performance characteristics. Thus, it requires careful consideration of hardware, performance, and workload characteristics for building a CSD-based storage system within a compute node. Therefore, storage architects are hesitant to build a storage system based on CSDs as there are no tools to determine the benefits of CSD-based compute nodes to meet the performance requirements compared to traditional nodes based on SSDs. In this work, we proposed an analytical model-based storage capacity planner called CsdPlan for system architects to build performance-effective CSD-based compute nodes. Our model takes into account the performance characteristics of the host system, targeted workloads, and hardware and performance characteristics of CSDs to be deployed and provides optimal configuration based on the number of CSDs for a compute node. Furthermore, CsdPlan estimates and reduces the total cost of ownership (TCO) for building a CSD-based compute node. To evaluate the efficacy of CsdPlan, we selected two commercially available CSDs and four representative big data analysis workloads. [ABSTRACT FROM AUTHOR]

Published
2024
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46. Tripled critical current in racetrack coils made of Bi-2212 Rutherford cables with overpressure processing and leakage control

Author

Zhang, Kai, Higley, Hugh, Ye, Liyang, Gourlay, Steve, Prestemon, Soren, Shen, Tengming, Bosque, Ernesto, English, Charles, Jiang, Jianyi, Kim, Youngjae, Lu, Jun, Trociewitz, Ulf, Hellstrom, Eric, and Larbalestier, David

Subjects
Engineering, Electronics, Sensors and Digital Hardware, Physical Sciences, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Materials engineering, Condensed matter physics
Abstract

We fabricated three racetrack coils (RC1, RC2, and RC3) from Bi-2212 Rutherford cables (17-strand, thickness × width = 1.44 mm × 7.8 mm, strand diameter = 0.8 mm) and applied overpressure processing heat treatment (OPHT). The quench currents of RC1 and RC2 reached 5268 A and 5781 A, respectively, despite them still, surprisingly, exhibiting some Bi-2212 leakage to the surface. After removing most of the leakages using a simple-to-implement insulation scheme, the quench current of RC3 improved to 6485 A, which is about three times the average quench current of a dozen racetrack coils that had been fabricated and reacted using the conventional 1 bar heat treatment. The results confirm the effectiveness of the OPHT technology and the new leakage control scheme for coils made from Bi-2212 Rutherford cables. Coils exhibited an increased quench current with increasing the current ramp rate from 5 to 200 A s-1; they were quite stable against point and transient disturbances, and were capable of adsorbing persistent Joule heating at ∼80 mW for >15 s before quenching. These behaviors are different from Nb-Ti and Nb3Sn accelerator magnets. Overall, our results provide a critical evaluation and verification of Bi-2212 wire and magnet technologies (wire, insulation, heat treatment, coil fabrication, and coil operation), reveal crucial new stability features of Bi-2212 magnets, and demonstrate technological options for it to become a practical high-field magnet technology.

Published
2018

49. Defect Passivation of 2D Semiconductors by Fixating Chemisorbed Oxygen Molecules via h‐BN Encapsulations

Author

Jung, Jin‐Woo, primary, Choi, Hyeon‐Seo, additional, Lee, Young‐Jun, additional, Kim, Youngjae, additional, Taniguchi, Takashi, additional, Watanabe, Kenji, additional, Choi, Min‐Yeong, additional, Jang, Jae Hyuck, additional, Chung, Hee‐Suk, additional, Kim, Dohun, additional, Kim, Youngwook, additional, and Cho, Chang‐Hee, additional

Published
2024
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