The Story of Antu (1) -A Hezhen Folktale Text with English and Japanese Translations-

科学研究費補助金 研究種目：基盤研究(C)(2)　課題番号：12610554　研究代表者：町田健　研究期間：2003-2005年度research repor

エネルギに基づく新型磨耗ダンパの開発に関する基礎研究

For the past several years, seismic isolation systems have been focused in the seismic design of industrial facilities. This paper deals with the response reduction effect by friction. Friction is expected to decrease the relative displacement by dissipating the vibration energy. The relative displacement between structure and support becomes larger at long period in the case of linear system. Therefore, the response reduction effect by friction should be utilized positively in the seismic design. However, the response magnification of acceleration is used in the seismic design. The acceleration becomes larger by stick and slip motion. Therefore, the response reduction effect by friction is evaluated from the viewpoint of energy. The ratio between elastic energy and input energy is utilized. In this paper, “Response Reduction Map” based on energy for long period friction system is suggested. This map shows the range that energy response ratio is less than the ratio of the linear system. The response reduction map without complex non-linear time history calculation can easily obtain the proper parameters, such as natural period or friction force. In this study, the response reduction map by the artificial earthquake wave calculated from the design spectrum is shown. Next, the advanced friction damper is developed by using above energy based result. The friction part of the advanced friction damper is constructed by using MR fluid. The characteristics of the friction part are evaluated.textapplication/pdfdepartmental bulletin pape

Evidence for Muon Neutrino Oscillation in an Accelerator-Based Experiment

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Analyses of wound and pathogen signal transduction mediated by WIPK, a mitogen-activated protein kinase from tobacco

奈良先端科学技術大学院大学博士(バイオサイエンス)doctoral thesi

Correlations between Decay and Translation Rates

<p>Pearson correlations together with corresponding <i>p</i>-values are shown for mRNA half-life versus (A) ribosome density and (B) ribosome occupancy. ORFs were, depending on mRNA half-life, grouped into all ORFs, 1,058 slowly decaying ORFs with <i>t</i>_1/2 ≥ 33 min, and 1,013 fast decaying ORFs with <i>t</i>_1/2 ≤ 13 min.</p

Folding Free Energies of 5′-UTRs Impact Post-Transcriptional Regulation on a Genomic Scale in Yeast - Table 1

Correlations between Secondary Structure in 5′-UTRs and Transcript Features</p

Folding Free Energies of 5′-UTRs Impact Post-Transcriptional Regulation on a Genomic Scale in Yeast - Table 3

Number of RBP Targets and Sequence Motifs Found in All mRNAs, mRNAs with Fast and Slow Decay Rates, and mRNAs with Strongly and Weakly Folded 5′-UTRs</p

Folding Free Energies of 5′-UTRs Impact Post-Transcriptional Regulation on a Genomic Scale in Yeast - Table 2

GO Terms Overrepresented among Genes with Strongly and Weakly Folded 5′-UTRs</p

Folding Free Energies of 5′-UTRs Impact Post-Transcriptional Regulation on a Genomic Scale in Yeast - Table 4

Pearson Correlations between Ribosome Density and ΔG in 5′-UTRs of Length 50, 100, and 200 nt</p

Comparison between Ribosome Densities and Folding Free Energies of 5′-UTRs

<p>(A) Scatter plot of mRNA ribosome density and folding free energy of the 5′-UTR (Δ<i>G</i>) for 5,888 ORFs.</p> <p>(B) ORFs were grouped based on the change in free energy (Δ<i>G</i>). For each energy group, the average ribosome density (±SEM) is shown. From left to right, the number of ORFs in each energy group used to calculate the average density was 573, 796, 1,214, 1,438, and 1,187.</p