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著者
吉田 忠
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.23, no.150, pp.73-80, 1984 (Released:2021-04-07)
著者
高田 誠二
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.147, pp.129-136, 1983 (Released:2021-09-24)

Traité Élementaire de Physique (depuis 1851)et Cours de Physique (depuis 1858) écrits par Adolphe Ganot (1804-1887) ont été diffusés aux plusieurs pays,le Japon inclusivement, soit directement par les éditions frangaises, soit par l'intermédiaire des traductions néerlandaise, anglaise etc., quelques-unes desquelles sont conservées dans la Collection Ancienne de l'École Agricole de Sapporo de la Bibliotheque de l'Université du Hokkaīdo. Selon les résultats d'examen sur ces livres et les renseignements biblio-graphique, sont exposés ici les états de réception et d'utilisation de ces ouvrages célèbres au Japon ainsi que les influences caractéristiques que ceux ont données sur l'introduction de la physique à ce pays.
著者
小松 真理子
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.147, pp.147-153, 1983 (Released:2021-09-24)

The basic problems of this paper are as follows. Why did Roger Bacon attach importance to mathematics in relation with natural sciences and didn't Thomas Aquinas do so? Why did Bacon advocate the original idea of Scientia Experimentalis and didn't Thomas do so? Bacon's praise of mathematics is due to his presupposition of multiplicatio specierum about general actions in the natural world. Because Thomas didn't have such presupposition and moreover made a rigid distinction between mathematics and natural sciences, that is sciences of natura, Thomas didn't attach importance to mathematics for natural sciences. On the other hand, because of this rigid distinction, Thomas' view to mathematics presents even certain modernity where mathematics is regarded as a free hypothetico-deductiva system according to imagination. Bacon couldn't regard mathematics as a hypothetical system, because mathematics of him was linking with structures of existence. Bacon's idea of Scientia Experimentalis containing the idea of "verification" was possible only upon Bacon's more mediaeval conception of "experience", and the idea of "verification" like Bacon was impossible upon Thomas' more modern conception of "experience". Verification of Bacon is certificatio of conclusion by experience, and it means real proof by noble experience which directly proves truth, and doesn't mean test as procedure. Such idea of verification wasn't able to occur to Thomas upon Thomas' conception of experience as sources of science. Therfore also here the situation is paradoxical, and Bacon's idea of verification doesn't have but superficial modernity. Finally criticism on Crombie's view is added.
著者
小林 龍彦 田中 薫
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.147, pp.154-159, 1983 (Released:2021-09-24)

We studied Problems of the Pierced Object in the Old Japanese Mathematics and we took statistics on these problems in mathematical Tablets. The investigation revealed the fact that many problems were studied during the Bunsei (1818〜1830), especially in and around Edo. And after that period they spread in the country. The main objects of this paper are to give the analysis of the above-mentioned investigation, especially to make the history of mathematical solution clear in these problems.

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出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.147, pp.177, 1983 (Released:2021-09-24)
著者
中村 邦光 板倉 聖宣
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.148, pp.193-205, 1983 (Released:2021-09-24)

In our last paper titled "The Value of Pi in the Edo Period" (Kagakusi Kenkyu, No.143, 1982. pp. 142-152), we did an exhaustive review of the books of native mathematics of Japan published in the Bunsei Era (1818-1830), and showed that these books could be divided into two types according to the two pi values (i.e. 3.14... and 3.16...) they respectively adopted. Specifically, the relatively advanced books of mathematics adopted 3.14..., while the value of 3.16... was generally used in popular booklets of the Jinkoki type and the like. It had been more than 150 years since Muramatsu correctly demonstrated the pi value of 3.14... in his Sanso published in 1663, but a considerable number of books still adopted 3.16... as the pi value in our period of study. Then, the next question would be how the correct value of 3.14... demonstrated by Muramatsu was handed down to the mathematicians of the Edo Period and disseminated. We carried our study a step further in this direction and tried to clarify the adoption process. As a result of our extensive research and analysis, we believe that we have successfully traced the adoption process of 3.14... instead of 3.16... as the value of pi. Among the various issues treated in this paper, the following points would be of particular interest. 1. After Muramatsu's Sanso (published in March,1663), the first book with 3.14... as the value of pi was Nozawa's Dȏkaishȏ (dated August, 1663 in the preface and published in November,1664), the interval between these books is less than two years. 2. Among the books of mathematics published during the ten years between 1663 and 1673, every one of those with 3.14... as the value of pi made an intentionnal alteration to the value adopted by its predecessor, such as 3.14 (→3.1404)→3.142→3.1416. This phenomenon had some connection with thebmovement to take over the traditional unsolved problems and it continued up to Miyake's Guȏ-sampȏ (published in 1699), in which the value of pi was further changed from 3.1416 to 3.141593. There were even a few cases of alteration from 3.142 to 3.14. 3. With the publication of Zȏho-sampȏ-ketsugishȏ (1684), Zohȏ-shimpenjinkȏki (1686) and Kaizanki-Kȏmoku (1687), the value of pi in the three most widely-read books of native mathematics in the Edo Era, Jinkȏki, Kaizanki and Sampȏ-Ketsugishȏ was altered from 3.16... to 3.14... 4. Upon examining all the books of native mathematics published between 1681 and 1690, we found that there was only one book (i.e. Kambara's Sankanki published in 1685) that had not altered the value of pi to 3.14.... and still used 3.16... All the remaining ten books adopted the value of 3.14... Once having attained this stage, how did it come about that the popular books of native mathematics fell back to the value of pi of 3.16... without any apparent hesitation ? A report, on this issue is now in preparation.
著者
溝口 元
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.146, pp.99-106, 1983 (Released:2021-09-29)

Dainihonbunmeikyokai (The Great Japanese Culture Society) was the private society and was founded in 1908 with the aid of many prominant scholars and financiers. The president of the society was Shigenobu Okuma (1838-1922), who was the poHtician and founder of Waseda University. The activities of the society were the publication of introducing foreign culture including social science, human science and natural science, which originally published in Europe and USA, analysis of world situation and popular cultural lecture. In the present study, we analyzed the character of the part of natural science published by the society. The total number of the publication is 241 and that of natural science books is 35 including 11 science of science,18 biology, 2 chemistry and 4 engineering. There was no publication of mathematics and physics. This point was markedly different from the books treated by "Nature" and "Science". The originally publishing countries are 17 UK,10 USA, 3 France,1 Germany and 3 books are edited by the society. The selection of the books is probably due to the influence of commissioner of the society such as Chiyomatsu Ishikawa (1861-1935, Biologist) and Matajiro Yokoyama (1860-1942, Geologist) and the inclination of the popular science movement at late Meiji and Taisho period (1908-1924).

1 0 0 0 OA 紹介

出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.146, pp.120, 1983 (Released:2021-10-06)

1 0 0 0 OA 紹介

出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.145, pp.57, 1983 (Released:2021-10-06)
著者
小林 龍彦 田中 薫
出版者
日本科学史学会
雑誌
科学史研究 (ISSN:21887535)
巻号頁・発行日
vol.22, no.145, pp.47-50, 1983 (Released:2021-10-06)

Toshisada ENDO, states that the first discovery of cycloid during the Bunsei period (1818〜1828) is attributed to Nei Wada (1787~1840). On the other hand, Yoshio MIKAMI pointed out that the same subject had already been studied by Tadao SHIZUKI (1760〜1806) in his Rekishō Shinsho (vol.1,1798; Vol.2, 1800; Vol.3, 1802). But these works seems to be insufficient, so we have discussed the same subject from astronomical points of view.