La notion d'enseignement parfait (yuanjiao) dans la pensée de Mou Zongsan (1909-1995)

Personnage central du néoconfucianisme contemporain, Mou Zongsan (1909-1995) a écrit un nombre impressionnant de livres philosophiques. Loin d’ignorer les penseurs d’autres courants, il les intègre à ses théories pour en utiliser les forces. Ainsi, il s’intéresse au concept d’enseignement parfait (yuanjiao圓教). Cette notion fut introduite par l’école bouddhique Tiantai (Tiantai天台). Après une classification de tous les enseignements bouddhiques, il fut conclu que l’enseignement parfait consiste en un enseignement complet reflétant parfaitement l’intention ultime du Bouddha. Mou considère quatre critères pour déterminer quelle doctrine est conforme à cette idée : la préservation de tout ce qui existe, la possibilité pour tous d’atteindre l’illumination, englober tout sans distinction et utiliser un langage qu’il qualifie de non analytique. Dans cette étude, nous allons examiner l’utilisation faite par Mou du concept d’enseignement parfait. Il démontre la nécessité pour l’être humain d’avoir un esprit qui saisit à la fois la sphère phénoménale et nouménale. De cette façon, tout ce qui compose la réalité, pur et impur, est conservé. Il emprunte ensuite le concept du summum bonum kantien, c’est-à-dire le ratio proportionnel entre la vertu et le bonheur, et le révise à l’aide de l’enseignement parfait. Le résultat est tout à fait étonnant : l’être humain possède l’intuition intellectuelle, normalement réservé à Dieu chez Kant, et est ainsi responsable de son propre bonheur grâce à l’accomplissement d’actions morales. Cependant, le bouddhisme ne fournirait pas le cadre théorique idéal pour la notion très importante du summum bonum puisque l’aspect moral n’y serait pas assez développé. Mou affirme que, malgré leur origine bouddhique, les critères qui définissent un enseignement parfait peuvent être appliqués à d’autres courants de pensée. Il propose donc le confucianiste Wang Longxi王龍溪 (Wang Ji王畿 1498- 1583), dont les théories correspondent aux caractéristiques de l’enseignement parfait, pour établir un concept du summum bonum novateur.

Eco-car : a perfect vehicle for technical design teaching?

Design methods and tools are generally best learned and developed experientially [1]. Finding appropriate vehicles for delivering these to students is becoming increasingly challenging, especially when considering only those that will enthuse, intrigue and inspire. This paper traces the development of different eco-car design and build projects which competed in the Shell Eco-Marathon. The cars provided opportunities for experiential learning through a formal learning cycle of CDIO (Conceive, Design, Implement, Operate) or the more traditional understand, explore, create, validate, with both teams developing a functional finished prototype. Lessons learned were applied through the design of a third and fourth eco-car using experimental techniques with bio-composites, combining the knowledge of fibre reinforced composite materials and adhesives with the plywood construction techniques of the two teams. The paper discusses the importance of applying materials and techniques to a real world problem. It will also explore how eco-car and comparing traditional materials and construction techniques with high tech composite materials is an ideal teaching, learning and assessment vehicle for technical design techniques.

Teaching clinical anatomy of the female pelvic floor to undergraduate students: A critical review of nevralgic points

Pelvic floor anatomy is complex and its three-dimensional organization is often difficult to understand for both undergrad- uate and postgraduate students. Here, we focused on several critical points that need to be considered when teaching the perineum. We have to deal with a mixed population of students and with a variety of interest. Yet, a perfect knowledge of the pelvic floor is the basis for any gynecologist and for any surgical intervention. Our objectives are several-fold; i) to estab- lish the objectives and the best way of teaching, ii) to identify and localize areas in the female pelvic floor that are suscepti- ble to generate problems in understanding the three-dimensional organization, iii) to create novel approaches by respecting the anatomical surroundings, and iv) prospectively, to identify elements that may create problems during surgery i.e. to have a closer look at nerve trajectories and on compression sites that may cause neuralgia or postoperative pain. A feedback from students concludes that they have difficulties to assimilate this much information, especially the different imaging tech- niques. Eventually, this will lead to a severe selection of what has to be taught and included in lectures or practicals. Another consequence is that more time to study prosected pelves needs to be given.

The perfect space: classroom environments and learning outcomes

Presentation at the Ontario Library Association Super Conference, January 28-21, 2015, Toronto, ON.

A Low Cost Controller Board for Teaching Robotics

This paper presents the Smarty Board; a new micro-controller board designed specifically for the robotics teaching needs of Australian schools. The primary motivation for this work was the lack of commercially available and cheap controller boards that would have all their components including interfaces on a single board. Having a single board simplifies the construction of programmable robots that can be used as platforms for teaching and learning robotics. Reducing the cost of the board as much as possible was one of the main design objectives. The target user groups for this device are the secondary and tertiary students, and hobbyists. Previous studies have shown that equipment cost is one of the major obstacles for teaching robotics in Australia. The new controller board was demonstrated at high-school seminars. In these demonstrations the new controller board was used for controlling two robots that we built. These robots are available as kits. Given the strong demand from high-school teachers, new kits will be developed for the next robotic Olympiad to be held in Australia in 2006.