310,586 research outputs found
DBLP-derived labeled data for author name disambiguation
This is a DBLP-derived labeled data originally created by Dr. C. Lee Giles at Penn State University and filtered for duplicate removal and error correction by Dr. Jinseok Kim at University of Michigan. For more details, see references below.1. Kim, Jinseok (2018). Evaluating author name disambiguation for digital libraries: a case of DBLP. Scientometrics. doi:10.1007/s11192-018-2824-5 2. Kim, Jinseok & Kim, Jenna (2018). The impact of imbalanced training data on machine learning for author name disambiguation. Scientometrics. doi: 10.1007/s11192-018-2865-9Each row refers to an author name instance with following feature information separated by tab.author name: full name string extracted from DBLPunique author id: labels assigned manually by Dr. C. Lee Giles's teampaper id: assigned by Dr. Jinseok Kimauthor list: names of authors in the byline of the paperyear: publication yearvenue: conference or journal namestitle: stopwords removed and stemmed by the Porter's stemmerIf you want to use this dataset, please consider to cite papers below.For the original dataset: Han, H., Giles, L., Zha, H., Li, C., & Tsioutsiouliklis, K. (2004). Two Supervised Learning Approaches for Name Disambiguation in Author Citations. JCDL 2004: Proceedings of the Fourth ACM/IEEE Joint Conference on Digital Libraries, 296-305. doi:10.1145/996350.996419For the filtered dataset: 1. Kim, Jinseok (2018). Evaluating author name disambiguation for digital libraries: a case of DBLP. Scientometrics. doi:10.1007/s11192-018-2824-5 or2. Kim, Jinseok & Kim, Jenna (2018). The impact of imbalanced training data on machine learning for author name disambiguation. Scientometrics. doi: 10.1007/s11192-018-2865-9</div
Bio-vison 2016: The second national framework plan for biotechnology promotion in Korea
This research was funded by the Specific Research
and Development Project of the Ministry of Science
and Technology.This material is based on Bio-Vision
2016 and its Report [5, 6].We are very grateful to the
following members of the Biotechnology Policy Research
Center: Young-Cheol Kim, Dong-Sub Yoon,
Moo Woong Kim, Eun Jung Kim, Su Gil Kim, Mi jeong
Park, Seong-Hoon Park, Oh-Min Joung, and Seung-
Hoo Shin
Efficient on-chip decoupling capacitor design on an 8-bit microcontroller to reduce simultaneous switching noise and electromagnetic radiated emission
We have thoroughly investigated the effect of on-chip decoupling capacitors on the simultaneous switching noise (SSN) and the radiated emission. Furthermore, we have successfully demonstrated an efficient design method for on-chip decoupling capacitors on an 8-bit microcontroller without increasing the die size, which results in more than 10 dB of suppressed radiated emission.The authors are grateful to Young-hwan Yun, Seog-heon Ham, Yong-hee Lee and Do-won Kim of Samsung Electronics, who provided the test IC chip layout and fabrication. We would like to thank D.K.Han, Y.S.Park, H.J.Yoon and M.K.Oh of Hynix Semiconductor for the fabrication of the controller IC chip being tested. We also thank H.W.Shim of ETRI-Korea for giving assistance with the EMI measurement, and Young-dae Kim of TESCOM who provided the TEM cell
Symplocarpus koreanus J. S. Lee, S. H. Kim & S. C. Kim 2021
Symplocarpus koreanus J.S. Lee, S.H. Kim & S.C. Kim (2021: 2) Isotype: KOREA, Gangwon-do: Chuncheon-si, Sabuk-myeon, Goseong-ri, Mt. Yonghwasan, 21 March 2020, S. C. Kim 200321500 (NIBRVP815477; Fig. 1 -23). Paratypes: KOREA, Gyeonggi-do: Gapyeong-gun, Buk-myeon, Baekdun-ri, Mt. Yeoninsan, 3 May 2013, W. B . Lee s.n. (NIBRVP517078); Gapyeong-gun, Oeseo-myeon, Mt. Hwayasan, 26 June 2007, W. K. Paik VP-KB-377062-0173 (NIBRVP815507); Gapyeonggun, Sang-myeon, Haenghyeon-ri, Mt. Chungnyeongsan, 31 March 2012, J. H . Kim, Y. J. Kim & I. S. Yoon KIMJH12006 (3 sheets, NIBRVP355001); Gapyeong-gun, Sang-myeon, Haenghyeon-ri, Mt. Chungnyeongsan, 29 March 2016, G. H . Nam, J. H. Kim & J. K. Hong L 16001 (NIBRVP550794); Gapyeong-gun, Seorak-myeon, Mt. Yumyeongsan, 4 April 2008, B. K . Kwon 080404-375 (NIBRVP532404); Gapyeong-gun, Seorak-myeon, Mt. Yumyeongsan, 4 April 2008, G. Y . Chung ANH-en-080404- 001 (NIBRVP197125); Hanam-si, Baealmi-dong, Mt. Geomdansan, 3 April 2007, J. O . Hyun, H. K. Park & J. A. Eom VP-NAPI-377054-092 (NIBRVP111433); Namyangju-si, Hwado-eup, Mt. Cheonmasan, 15 April 2007, W. K . Paik VP-KB-377061-0133 (NIBRVP815506); Namyangju-si, Hwado-eup, Mt. Cheonmasan, 22 March 2013, Song et al. s.n. (NIBRVP464822); Namyangjusi, Onam-eup, Onam-ri, Mt. Cheonmasan, 6 April 2009, G. H . Nam, M. H. Kim & J. H. Lee VS 15 (NIBRVP206699); Namyangjusi, Onam-eup, Onam-ri, Mt. Cheonmasan, 6 April 2009, G. H . Nam, M. H. Kim & J. H. Lee VS16 (2 sheets, NIBRVP206700); Namyangju-si, Mt. Chungnyeongsan, 28 March 1999, S. P . Hong & K. W. Park 411 (NIBRVP102296). Gangwon-do: Cheorwon-gun, Geunnam-myeon, Mt. Gwangdeoksan, 12 May 1997, S. P . Hong & H. S. Choi 99 (NIBRVP102297); Donghae-si, Bugok-dong, Mita Temple, 26 April 2011, G. H . Nam & W. J. Jeong SHY2-34 (NIBRVP284290); Gangneung-si, Wangsan-myeon, Mt. Hwaranbong, 30 April 2009, J. H . Kim & H. J. Kim VP-KB-0904-0071 (NIBRVP318582); Hwacheon-gun, Mt. Baekjeoksan, 24 May 2000, K . Ch. Yang & J. D. Jung s.n. (NIBRVP102304, NIBRVP102305); Hwacheon-gun, Mt. Baekjeoksan, 3 August 2000, J. H . Kim & D. K. Kim 49 (NIBRVP102307); Hwacheon-gun, Sanae-myeon, Mt. Gwangdoeksan, 7 April 2009, G. H . Nam, M. H. Kim & J. H. Lee VS24 (2 sheets, NIBRVP206708); Hwacheon-gun, Sanae-myeon, Mt. Gwangdoeksan, 7 April 2009, G. H . Nam, M. H. Kim & J. H. Lee VS25 (2 sheets; NIBRVP206709). Chungcheongbuk-do: Danyang-gun, Gagok-myeon, Mt. Sobaecksan, 17 May 1999, C. W . Park, H. W. Lee & J. Koh 10315 (NIBRVP815505); Danyang-gun, Gagok-myeon, Mt. Sobaeksan, 20 April 2007, G. Y . Chung ANH-en-070420-013 (NIBRVP121631). Jeollabuk-do: Jangsu-gun, Gyenam-myeon, Jangan-ri, 21 September 1997, B. Y . Sun & C. H. Kim 10361 (NIBRVP815504); Jangsu-gun, Gyenam-myeon, Mt. Jangansan, 19 May 2007, B. Y . Sun 2271 (NIBRVP128343); Jangsu-gun, Gyenam-myeon, Mt. Jangansan, 19 June 2009, J. K . Ahn, S. J. Lee & Y. W. Lee CH 40006 (NIBRVP266477); Jangsu-gun, Gyenammyeon, Mt. Jangansan, 19 June 2009, J. K . Ahn, S. J. Lee & Y. W. Lee CH 40239 (NIBRVP266707); Jinan-gun, Jucheon-myeon, Daebul-ri, Mt. Unjangsan, without date, C. H . Kim & S. H. Lee 50051 (3 sheets, NIBRVP537859). Gyeongsangnam-do: Geochanggun, Buksang-myeon, Mt. Deogyusan hyangjeokbong-satgatgoljae, 31 May 2006, B. Y . Sun 1577 (4 sheets, NIBRVP119643). Note: The holotype is deposited in SKK.Published as part of Jang, Hyun-Do, Hyun, Chang-Woo, Ryu, Seah & Lee, Sang-Jun, 2022, Type specimens of vascular plants in the herbarium of the National Institute of Biological Resources (II), pp. 229-243 in Phytotaxa 539 (3) on page 237, DOI: 10.11646/phytotaxa.539.3.2, http://zenodo.org/record/636408
Near-complete teleportation of a superposed coherent state
©2004 The American Physical Society
URL: http://link.aps.org/abstract/PRA/v70/e032327
doi:10.1103/PhysRevA.70.032327
PACS: 03.67.Hk, 03.65.Ud, 42.50.-pThe four Bell-type entangled coherent states, \alpha]\-alpha]+/-alpha]\alpha] and \alpha]\alpha]+/-\-alpha]\alpha], can be discriminated with a high probability using only linear optical means, as long as \alpha\ is not too small. Based on this observation, we propose a simple scheme to almost completely teleport a superposed coherent state. The nonunitary transformation that is required to complete the teleportation can be achieved by embedding the receiver's field state in a larger Hilbert space consisting of the field and a single atom and performing a unitary transformation on this Hilbert space.This research was supported by Korea Research Foundation Grant No. KRF-2002-070-C00029.We wish to thank Dr. J. Kim and Dr. B. A. Nguyen of KIAS and Professor M. S. Kim and Dr. H. Jeong of Queens University, Belfast for helpful discussions
Fimbristylis driziae Jonghwan Kim & M. Kim 2015
Fimbristylis driziae Jonghwan Kim & M. Kim (2015: 9), ‘drizae’. Isotype: KOREA, Jeollabuk-do: Jeongeup-si, Lake Sucheong, 28 September 2013, J. H. Kim 13159-2 (NIBRVP814952; Fig. 1 -27). Paratypes: KOREA, Chungcheongnam-do: Buyeo-gun, Chunghwa-myeon, Gahwa-ri, Deogyongjeosuji, 24 September 2009, J . D. Jung & C. K. Kim 0909181-1 (NIBRVP254635); Buyeo-gun, Eunsan-myeon, Chugyungbong, 3 September 2000, S. M . Seo et al. 382 (NIBRVP24469). Daegu-si: Dalseong-gun, Habin-myeon, Hasan-ri, Nakdong River, 7 October 2010, K. S . Jeong & J. S. Yun 480 (NIBRVP274479). Gyeongsangnam-do: Hapcheon-gun, Deokgok-myeon, Podu-ri, Mt.Sohaksan, 2 October 2007, S. C . Ko & J. H. Kim VP-KB-358061-0174 (NIBRVP496500). Jeollanam-do: Muan-gun, Samhyang-myeon, Yugyo-ri, Namyangje, 11 October 2009, J. H . Kim & Y. H. Jo KJH472 (NIBRVP275118); Jangseong-gun, Lake Jangseong, 28 August 2012, J. H . Kim 12043 (NIBRVP814953). Note: Kim & Kim (2015) cited J. H . Kim 13158 as its holotype and isotypes. All of the isotype specimens, however, were stamped as isotypes, and were recorded as J. H . Kim 13159- 1 in NNH and J. H . Kim 13159- 2 in KB (NIBRVP814952). Therefore, according to Art. 9.2 of the Code (Turland et al. 2018), a correction to the isotype citation is needed. In addition, Kim & Kim (2015) designated “ Jeollanam-do: Gangjin-gun, 19 August 2012, J. H. Kim 12043 ” as a paratype. One specimen of J. H . Kim 12043 (NIBRVP814953) was transferred to KB from JNU and stamped as the paratype. However, it seems that the specimen is not a type because it was collected from a different locality (“ Jeollanam-do, Jangseong-gun, Lake Jangseong ”) and on a different date (“ 28 August 2012 ”). The holotype is conserved in KH (!).Published as part of Jang, Hyun-Do, Hyun, Chang-Woo, Ryu, Seah & Lee, Sang-Jun, 2022, Type specimens of vascular plants in the herbarium of the National Institute of Biological Resources (II), pp. 229-243 in Phytotaxa 539 (3) on page 238, DOI: 10.11646/phytotaxa.539.3.2, http://zenodo.org/record/636408
Kim H. Vance and an Unidenitified Woman
This photograph features Kim H. Vance and an unidenitified women. This photograph was likely taken at the 2000 Abraham Lincoln Forum.https://scholarsjunction.msstate.edu/fvw-photographs/1952/thumbnail.jp
Graph-based Object Detection and Tracking in H.264/AVC Bitstreams for Surveillance Video
In this paper we present a novel method to detect and track moving objects in H.264/AVC bitstreams by processing motion vector and residue information. The encoded blocks with nonzero motion vectors and residues are first detected as moving object candidates. A spatio-temporal graph in video sequences is then constructed to represent groups of blocks in each frame and their associations to the other groups of blocks in subsequent frames. Identification and refinement of ROIs for moving objects being tracked are done by graph matching and adaptive ROI-size adjustment. The experimental results show that the proposed method can correctly identify real moving objects from frame to frame and can effectively detect small-sized objects and objects with small motion vectors and residues, as well as by recognizing moving objects even under occlusion
Taeyeung Kim
학위논문(석사)--아주대학교 일반대학원 :의생명학과,2011. 2Ⅰ. INTRODUCTION 1
Ⅱ. MATERIALS AND METHODS 5
A. HBV plasmid DNA construction 5
B. Cell culture and transfection 8
C. Isolation of core particles 9
D. RNase protection assay (RPA) 9
E. Core particle Western blotting 10
F. Southern blotting 11
G. SDS-PAGE and Western blotting 11
Ⅲ. RESULT 12
A. HBV P constructs containing DHBV P residues in RNase H domain 12
B. Amino acid residues from 800 to 826 in C-terminus of the RNase H are critical for pgRNA encapsidaion and DNA synthesis. 14
C. The small motif substituted HBV RNase H domain mutants at C-terminus have ability to support
HBV DNA synthesis. 21
D. The small motif substituted HBV RNase H domain mutants at C-terminus have ability to support
HBV pgRNA encapsidation. 23
E. A leucine residue at position 806 in HBV P protein is important for viral genome replication. 26
F. A leucine residue at position 806 in HBV P protein is important for pgRNA encapsidation. 28
Ⅳ. DISCUSSION 29
Ⅴ. CONCLUSION 31
REFERENCES 32
국문요약 38MasterHepatitis B Virus (HBV) DNA polymerase (P) protein consisting of terminal protein (TP), spacer, reverse transcriptase (RT), and RNase H, plays critical roles in viral assembly and replication. RNase H domain is required for HBV DNA replication, however critical motif or amino acid residues in the RNase H domain for the HBV replication has not been extrensively demonstrated yet. In the present study, several chimeras of P protein by substituting Duck hepatitis B virus (DHBV) sequences were constructed. Accordingly, we tested a series of P protein chimeras in which several substitution mutants were disigned to contain various amino acids of DHBV P protein. It is found that amino acid residues from 800 to 826 (800SRPLLRLPFQPTTGRTSLYAVSPSVPS826) in C -terminus of the RNase H domain are required to complete HBV replication. HBV P protein mutants in which single amino acid residue was substituted were examined for the rescue of HBV replication. Among these mutants tested, L806T mutant P protein have a defect in pgRNA encapsidation and viral DNA synthesis, demonstrating that leucine at position 806 is critical for HBV replication
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