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200 results on '"Kwon, Youngeun"'

1. LazyDP: Co-Designing Algorithm-Software for Scalable Training of Differentially Private Recommendation Models

Author

Lim, Juntaek, Kwon, Youngeun, Hwang, Ranggi, Maeng, Kiwan, Suh, G. Edward, and Rhu, Minsoo

Subjects
Computer Science - Information Retrieval, Computer Science - Cryptography and Security, Computer Science - Machine Learning
Abstract

Differential privacy (DP) is widely being employed in the industry as a practical standard for privacy protection. While private training of computer vision or natural language processing applications has been studied extensively, the computational challenges of training of recommender systems (RecSys) with DP have not been explored. In this work, we first present our detailed characterization of private RecSys training using DP-SGD, root-causing its several performance bottlenecks. Specifically, we identify DP-SGD's noise sampling and noisy gradient update stage to suffer from a severe compute and memory bandwidth limitation, respectively, causing significant performance overhead in training private RecSys. Based on these findings, we propose LazyDP, an algorithm-software co-design that addresses the compute and memory challenges of training RecSys with DP-SGD. Compared to a state-of-the-art DP-SGD training system, we demonstrate that LazyDP provides an average 119x training throughput improvement while also ensuring mathematically equivalent, differentially private RecSys models to be trained.

Published
2024
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2. Training Personalized Recommendation Systems from (GPU) Scratch: Look Forward not Backwards

Author

Kwon, Youngeun and Rhu, Minsoo

Subjects
Computer Science - Hardware Architecture, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Personalized recommendation models (RecSys) are one of the most popular machine learning workload serviced by hyperscalers. A critical challenge of training RecSys is its high memory capacity requirements, reaching hundreds of GBs to TBs of model size. In RecSys, the so-called embedding layers account for the majority of memory usage so current systems employ a hybrid CPU-GPU design to have the large CPU memory store the memory hungry embedding layers. Unfortunately, training embeddings involve several memory bandwidth intensive operations which is at odds with the slow CPU memory, causing performance overheads. Prior work proposed to cache frequently accessed embeddings inside GPU memory as means to filter down the embedding layer traffic to CPU memory, but this paper observes several limitations with such cache design. In this work, we present a fundamentally different approach in designing embedding caches for RecSys. Our proposed ScratchPipe architecture utilizes unique properties of RecSys training to develop an embedding cache that not only sees the past but also the "future" cache accesses. ScratchPipe exploits such property to guarantee that the active working set of embedding layers can "always" be captured inside our proposed cache design, enabling embedding layer training to be conducted at GPU memory speed., Comment: Accepted for publication at the 49th IEEE/ACM International Symposium on Computer Architecture (ISCA-49), 2022

Published
2022

4. Tensor Casting: Co-Designing Algorithm-Architecture for Personalized Recommendation Training

Author

Kwon, Youngeun, Lee, Yunjae, and Rhu, Minsoo

Subjects
Computer Science - Hardware Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Retrieval, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing
Abstract

Personalized recommendations are one of the most widely deployed machine learning (ML) workload serviced from cloud datacenters. As such, architectural solutions for high-performance recommendation inference have recently been the target of several prior literatures. Unfortunately, little have been explored and understood regarding the training side of this emerging ML workload. In this paper, we first perform a detailed workload characterization study on training recommendations, root-causing sparse embedding layer training as one of the most significant performance bottlenecks. We then propose our algorithm-architecture co-design called Tensor Casting, which enables the development of a generic accelerator architecture for tensor gather-scatter that encompasses all the key primitives of training embedding layers. When prototyped on a real CPU-GPU system, Tensor Casting provides 1.9-21x improvements in training throughput compared to state-of-the-art approaches.

Published
2020

5. Centaur: A Chiplet-based, Hybrid Sparse-Dense Accelerator for Personalized Recommendations

Author

Hwang, Ranggi, Kim, Taehun, Kwon, Youngeun, and Rhu, Minsoo

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Information Retrieval, Computer Science - Machine Learning
Abstract

Personalized recommendations are the backbone machine learning (ML) algorithm that powers several important application domains (e.g., ads, e-commerce, etc) serviced from cloud datacenters. Sparse embedding layers are a crucial building block in designing recommendations yet little attention has been paid in properly accelerating this important ML algorithm. This paper first provides a detailed workload characterization on personalized recommendations and identifies two significant performance limiters: memory-intensive embedding layers and compute-intensive multi-layer perceptron (MLP) layers. We then present Centaur, a chiplet-based hybrid sparse-dense accelerator that addresses both the memory throughput challenges of embedding layers and the compute limitations of MLP layers. We implement and demonstrate our proposal on an Intel HARPv2, a package-integrated CPU+FPGA device, which shows a 1.7-17.2x performance speedup and 1.7-19.5x energy-efficiency improvement than conventional approaches., Comment: Accepted for publication at the 47th IEEE/ACM International Symposium on Computer Architecture (ISCA-47), 2020

Published
2020

6. NeuMMU: Architectural Support for Efficient Address Translations in Neural Processing Units

Author

Hyun, Bongjoon, Kwon, Youngeun, Choi, Yujeong, Kim, John, and Rhu, Minsoo

Subjects
Computer Science - Hardware Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing
Abstract

To satisfy the compute and memory demands of deep neural networks, neural processing units (NPUs) are widely being utilized for accelerating deep learning algorithms. Similar to how GPUs have evolved from a slave device into a mainstream processor architecture, it is likely that NPUs will become first class citizens in this fast-evolving heterogeneous architecture space. This paper makes a case for enabling address translation in NPUs to decouple the virtual and physical memory address space. Through a careful data-driven application characterization study, we root-cause several limitations of prior GPU-centric address translation schemes and propose a memory management unit (MMU) that is tailored for NPUs. Compared to an oracular MMU design point, our proposal incurs only an average 0.06% performance overhead.

Published
2019

7. TensorDIMM: A Practical Near-Memory Processing Architecture for Embeddings and Tensor Operations in Deep Learning

Author

Kwon, Youngeun, Lee, Yunjae, and Rhu, Minsoo

Subjects
Computer Science - Machine Learning, Computer Science - Hardware Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Neural and Evolutionary Computing
Abstract

Recent studies from several hyperscalars pinpoint to embedding layers as the most memory-intensive deep learning (DL) algorithm being deployed in today's datacenters. This paper addresses the memory capacity and bandwidth challenges of embedding layers and the associated tensor operations. We present our vertically integrated hardware/software co-design, which includes a custom DIMM module enhanced with near-data processing cores tailored for DL tensor operations. These custom DIMMs are populated inside a GPU-centric system interconnect as a remote memory pool, allowing GPUs to utilize for scalable memory bandwidth and capacity expansion. A prototype implementation of our proposal on real DL systems shows an average 6.2-17.6x performance improvement on state-of-the-art recommender systems., Comment: Accepted for publication at the 52nd IEEE/ACM International Symposium on Microarchitecture (MICRO-52), 2019

Published
2019

8. Beyond the Memory Wall: A Case for Memory-centric HPC System for Deep Learning

Author

Kwon, Youngeun and Rhu, Minsoo

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Hardware Architecture, Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing
Abstract

As the models and the datasets to train deep learning (DL) models scale, system architects are faced with new challenges, one of which is the memory capacity bottleneck, where the limited physical memory inside the accelerator device constrains the algorithm that can be studied. We propose a memory-centric deep learning system that can transparently expand the memory capacity available to the accelerators while also providing fast inter-device communication for parallel training. Our proposal aggregates a pool of memory modules locally within the device-side interconnect, which are decoupled from the host interface and function as a vehicle for transparent memory capacity expansion. Compared to conventional systems, our proposal achieves an average 2.8x speedup on eight DL applications and increases the system-wide memory capacity to tens of TBs., Comment: Published as a conference paper at the 51st IEEE/ACM International Symposium on Microarchitecture (MICRO-51), 2018

Published
2019

13. Advanced Neural Functional Imaging in C. elegans Using Lab-on-a-Chip Technology.

Author

Kwon, Youngeun, Kim, Jihye, Son, Ye Bin, Lee, Sol Ah, Choi, Shin Sik, and Cho, Yongmin

Subjects
LABS on a chip, NERVOUS system, MICROFLUIDICS, CALCIUM, CAENORHABDITIS elegans, ANATOMY
Abstract

The ability to perceive and adapt to environmental changes is crucial for the survival of all organisms. Neural functional imaging, particularly in model organisms, such as Caenorhabditis elegans, provides valuable insights into how animals sense and process external cues through their nervous systems. Because of its fully mapped neural anatomy, transparent body, and genetic tractability, C. elegans serves as an ideal model for these studies. This review focuses on advanced methods for neural functional imaging in C. elegans, highlighting calcium imaging techniques, lab-on-a-chip technologies, and their applications in the study of various sensory modalities, including chemosensation, mechanosensation, thermosensation, photosensation, and magnetosensation. We discuss the benefits of these methods in terms of precision, reproducibility, and ability to study dynamic neural processes in real time, ultimately advancing our understanding of the fundamental principles of neural activity and connectivity. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Real‐Time, Non‐Invasive Monitoring of Neuronal Differentiation Using Intein‐Enabled Fluorescence Signal Translocation in Genetically Encoded Stem Cell‐Based Biosensors.

Author

Lee, Euiyeon, Choi, Hye Kyu, Kwon, Youngeun, and Lee, Ki‐Bum

Subjects
NEURONAL differentiation, NEURAL stem cells, FLUORESCENCE, SIGNAL peptides, BIOSENSORS
Abstract

Real‐time and non‐invasive monitoring of neuronal differentiation helps to increase understanding of neuronal development and develop stem cell therapies for neurodegenerative diseases. Conventional methods such as RT‐PCR, western blotting, and immunofluorescence (IF), lack single‐cell‐level resolution and require invasive procedures, fixation, and staining. These limitations hinder accurate monitoring progress of neural stem cell (NSC) differentiation and understanding its functions. Herein, a novel approach is reported to non‐invasively monitor neuronal differentiation in real‐time using cell‐based biosensors (CBBs) that detects hippocalcin, biomarker of neuronal differentiation. To construct the hippocalcin sensor proteins, two different hippocalcin bioreceptors are fused to each split‐intein, carrying split‐nuclear localization signal (NLS) peptides, respectively, and fluorescent protein is introduced as reporter. CBBs operated in the presence of hippocalcin to generate functional signal peptides, which promptly translocated the fluorescence signal to the nucleus. The NSC‐based biosensor shows fluorescence signal translocation only upon neuronal differentiation and not undifferentiated stem cells or glial cells. Furthermore, this approach allows monitoring of neural differentiation at earlier stages than detected using IF staining. It is believed that novel CBBs offer an alternative to current techniques by capturing the dynamics of differentiation progress at the single‐cell‐level and providing a tool to evaluate how NSCs efficiently differentiate into neurons. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Cell-Based Sensors for the Detection of EGF and EGF-Stimulated Ca 2+ Signaling.

Author

Lee, Euiyeon, Shrestha, Keshab Lal, Kang, Seonhye, Ramakrishnan, Neethu, and Kwon, Youngeun

Subjects
CALCIUM ions, WNT signal transduction, EPIDERMAL growth factor, EPIDERMAL growth factor receptors, CETUXIMAB, PEPTIDES, DETECTORS
Abstract

Epidermal growth factor (EGF)-mediated activation of EGF receptors (EGFRs) has become an important target in drug development due to the implication of EGFR-mediated cellular signaling in cancer development. While various in vitro approaches are developed for monitoring EGF-EGFR interactions, they have several limitations. Herein, we describe a live cell-based sensor system that can be used to monitor the interaction of EGF and EGFR as well as the subsequent signaling events. The design of the EGF-detecting sensor cells is based on the split-intein-mediated conditional protein trans-cleavage reaction (CPC). CPC is triggered by the presence of the target (EGF) to activate a signal peptide that translocates the fluorescent cargo to the target cellular location (mitochondria). The developed sensor cell demonstrated excellent sensitivity with a fast response time. It was also successfully used to detect an agonist and antagonist of EGFR (transforming growth factor-α and Cetuximab, respectively), demonstrating excellent specificity and capability of screening the analytes based on their function. The usage of sensor cells was then expanded from merely detecting the presence of target to monitoring the target-mediated signaling cascade, by exploiting previously developed Ca2+-detecting sensor cells. These sensor cells provide a useful platform for monitoring EGF-EGFR interaction, for screening EGFR effectors, and for studying downstream cellular signaling cascades. [ABSTRACT FROM AUTHOR]

Published
2023
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38. Magnetic bead based immunoassay for autonomous detection of toxins

Author

Kwon, Youngeun, Hara, Christine A., Knize, Mark G., Hwang, Mona H., Venkateswaran, Kodumudi S., Wheeler, Elizabeth K., Bell, Perry M., Renzi, Ronald F., Fruetel, Julie A., and Bailey, Christopher G.

Subjects
Toxins -- Properties, Immunoassay -- Research, Biosensors -- Magnetic properties, Antibodies -- Properties, Viral antibodies -- Properties, Chemistry
Abstract

We are developing an automated system for the simultaneous, rapid detection of a group of select agents and toxins in the environment. To detect toxins, we modified and automated an antibody-based approach previously developed for manual medical diagnostics that uses fluorescent eTag reporter molecules and is suitable for highly multiplexed assays. Detection is based on two antibodies binding simultaneously to a single antigen, one of which is labeled with biotin while the other is conjugated to a fluorescent eTag through a cleavable linkage. Aqueous samples are incubated with the mixture of antibodies along with streptavidin-coated magnetic beads and a photoactive porphyrin complex. In the presence of antigen, a molecular complex is formed where the cleavable linkage is held in proximity to the photoactive group. Upon excitation at 680 nm, free radicals are generated, which diffuse and cleave the linkage, releasing the eTags. Released eTags are analyzed using capillary gel electrophoresis with laser-induced fluorescence detection. Limits of detection for ovalbumin and botulinum toxoid individually were 4 (or 80 pg) and 16 ng/mL (or 320 pg), respectively, using the manual assay. In addition, we demonstrated the use of pairs of antibodies from different sources in a single assay to decrease the rate of false positives. Automation of the assay was demonstrated in a flow-through format with higher LODs of 32 ng/mL (or 640 ng) each of a mixture of ovalbumin and botulinum toxoid. This versatile assay can be easily modified with the appropriate antibodies to detect a wide range of toxins and other proteins.

Published
2008

41. Antibody arrays prepared by cutinase-mediated immobilization on self-assembled monolayers

Author

Kwon, Youngeun, Han, Zhaozhong, Karatan, Ece, Mrksich, Milan, and Kay, Brian K.

Subjects
Viral antibodies -- Research, Antibodies -- Research, Chemistry
Abstract

Antibody arrays hold considerable potential in a variety of applications including proteomics research, drug discovery, and diagnostics. Many of the schemes used to fabricate the arrays fail to immobilize the antibodies at a uniform density or in a single orientation; consequently, the immobilized antibodies recognize their antigens with variable efficiency. This paper describes a strategy to immobilize antibodies in a single orientation, with a controlled density, using the covalent interaction between cutinase and its suicide substrate. Protein fusions between cutinase and five antibodies of three different types (scFv, VHH, and FN3) were prepared and immobilized upon self-assembled monolayers (SAMs) presenting a phosphonate capture ligand. The immobilized antibodies exhibit high affinity and selectivity for their target antigens, as monitored by surface plasmon resonance and fluorescence scanning. Furthermore, by changing the density of capture ligand on the SAM the density of the immobilized antibody could be controlled. The monolayers, which also present a tri(ethylene glycol) group, are inert to nonspecific adsorption of proteins and allow the detection of a specific antigen in a complex mixture. The demonstration of cutinase-directed antibody immobilization with insert SAMs provides a straightforward and robust method for preparing antibody chips.

Published
2004

42. Dependence of the rate of an interfacial Diels-Alder reaction on the steric environment of the immobilized dienophile: An example of enthalpy-entropy compensation

Author

Kwon, Youngeun and Mrksich, Milan

Subjects
Enthalpy -- Research, Quinone -- Chemical properties, Diels-Alder reaction -- Analysis, Chemistry
Abstract

The physical organic study of the relationship between the rate for an interfacial Diels-Alder reaction and the steric environment around the reacting molecules is detailed. The quinone groups positioned below the interface reacted with an enthalpy of activation that was 4Kcal/mol greater than did the quinones that were accessible at the interface and the reaction of the buried quinone proceeded with an entropy of activation that was more favourable by 13 eu, with a similar free energy of activation.

Published
2002

45. NeuMMU

Author

Hyun, Bongjoon, primary, Kwon, Youngeun, additional, Choi, Yujeong, additional, Kim, John, additional, and Rhu, Minsoo, additional

Published
2020
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47. TensorDIMM

Author

Kwon, Youngeun, primary, Lee, Yunjae, additional, and Rhu, Minsoo, additional

Published
2019
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