理工学研究科

システム創成工学専攻Division of Systems Innovation Engineering

第四次産業革命の時代において,IoTやAIによって既存の産業社会が大きく変革を遂げつつあり,これまでの要素技術の開発・改善ではなく,人・社会・産業全体をシステムとして捉え,高度な専門知識に加え広範な知識を兼ね備えた人材育成のための教育研究を展開する必要があります。本専攻は,電気電子通信,知能情報,機械,社会基盤・環境に関する広範囲な領域とその境界領域において,先端的な新技術と融合化技術を開拓するための教育・研究を実施し,環境やエネルギー危機を解決するための「持続可能な社会」への転換や,高度に電子情報化された「ユビキタス社会」への対応,未来の知能化した「機械システム」の構築,安全・安心を柱とした「社会基盤」の整備に貢献できる高度専門技術者,研究者の養成を目指します。

In this time of the fourth industrial revolution, our existing industrial society is continuing to see great change due to the IoT and AI, making it necessary to develop education and research that will foster talented personnel who can grasp people, society, and industry in its entirety as a system rather than developing and improving existing elemental technology, and have both highly specialized and extensive knowledge. The Division of Systems Innovation Engineering carries out research and education in a wide range of areas related to electrical and electronic communication, computer science and intelligent systems, mechanics, civil and environmental engineering, and their interfaces, in order to pioneer cutting-edge new technology and integrated technology; we aim to foster highly specialized engineers and researchers who can contribute to the move to a “sustainable society” to solve the environmental and energy crisis, handle the “ubiquitous society” with a high level of digitization, construct the intelligent “mechanical systems” of the future, and contribute to the maintenance of “civil engineering,” the pillar of safety and stability.

電気電子通信工学分野Electrical, Electronic, and Communication Engineering Area

下記の電気電子通信工学領域における最新の学術研究成果に基づく高度な教育研究を行い,高度な知識を持ち,自立して研究できる技術者・研究者の養成を行います。通信・電子システム工学領域では,電子情報産業の成長に欠くことのできない,無線通信システム,ディジタル信号処理システム,計測・制御システムなどに関する教育と研究を行っています。電子デバイス工学領域では,磁性材料や電子材料の特性や物性を調べるとともに,それを応用した磁気デバイス,高周波デバイス,光デバイスなどに関する教育と研究を行っています。電気エネルギー工学領域では,電気エネルギーの発生とそれによって起る環境問題をプラズマ技術で解決するための研究,電気エネルギー発生には不可欠な電気絶縁などの教育と研究を行っています。

In this area we carry out high-level research and education based on the latest academic research results in the Electrical, Electronic, and Communication Engineering areas below, fostering engineers and researchers who have a high level of knowledge and can undertake independent research.The Communication and Electronic System Engineering area offers education and research related to wireless communication systems, digital signal processing systems, and measurement and control systems, which are all indispensable to the growth of the electronic information industry.The Electronic Device Engineering area studies the characteristics and physical properties of magnetic materials and electronic materials, as well as providing education and undertaking research relating to magnetic devices, high frequency devices, and optical devices where these materials are used.The Electrical Energy Engineering area carries out research on solutions to electrical energy generation and the environmental issues it causes using plasma technology, offering education and research relating to electric insulation indispensable to electrical energy generation, etc.

機械工学分野Mechanical Engineering Area

下記3領域の最新の学術研究成果に基づく高度な教育研究を行い,高度な知識を持ち,自立して研究できる技術者・研究者の養成を行います。航空宇宙領域では,航空機・ロケット・宇宙機などを効率的に飛行・推進させるための技術,運動の制御や飛行効率を向上するためのシステム制御技術,航空宇宙機に用いられる材料の長寿命化・耐熱性向上・機能性向上技術,について最先端の研究を取り扱います。バイオ・ロボティクス領域では,人間の生活を支援するためのセンシング技術や制御技術,医療用ロボット・高齢者や障がい者のための自立支援ロボット・海洋および水産業の調査・管理に向けた水中ロボット,について最先端の研究を取り扱います。システムデザイン領域では,加工システムの最適化・加工精度の高度化・加工条件の最適化,流体現象・機械構造・表面テクスチャなどが複合的に性能に影響を与える熱流体システムや自然エネルギーシステムの最適化技術,について最先端の研究を取り扱います。

We foster engineers and researchers who have a high level of knowledge and the ability to carry out independent research, by providing high-level education and research opportunity based on the latest academic research results in the three areas below:In the Aerospace area, we carry out cutting-edge research on technology that will allow the efficient flight and propulsion of aircraft, rockets, and spacecraft, system control technology to improve the control of movement and efficiency of flight, and technology that will improve life expectancy, heat resistance, and functionality of materials used in aerospace vehicles.In the Biotechnology and Robotics area, we undertake cutting-edge research on sensing technology and control technology that supports people’s lifestyles, medical robots, robots that support the independence of the elderly and people with a disability, and underwater robots used for investigating and managing the ocean and fishing industry.In the System Design area, we carry out cutting-edge research focusing on the following topics: optimal design of processing systems, refinement of processing accuracy, optimization of processing condition, and optimization technology of thermal-fluid systems and natural energy systems that are affected by fluid phenomenon, mechanical structure and surface texture in a compound manner.

知能情報工学分野Computer Science and Intelligent Systems Area

インターネットとそれを取り巻く情報技術によって急速に変化している現代社会の中で,豊かな社会を維持発展させるために必須なコンピュータシステムの中核技術を担うのが知能情報工学です。本専攻の知能情報工学分野は,知能化によって人々の活動を支援する新しいコンピュータシステムの研究・開発を主導できる高度専門職業人・研究者の育成を目標としています。変化する世界に対応可能な高性能システムの開発のため,最適化や数え上げなど実社会で頻出する問題をグラフ理論等に基づいて素早く解くための高効率アルゴリズム,音響,光,画像等を聴覚や資格の特性に着目して効率よく処理するための知能情報処理システム,対象のモデル化に基づくインテリジェントシステムなどに関し,それらの設計能力を習得するための研究・教育を行います。

In our modern society, changing rapidly thanks to the Internet and surrounding information technology, the study of computer science and intelligent systems is responsible for the core technology of the computer systems necessary to maintain and develop our affluent society.The Computer Science and Intelligent Systems Area specialism aims to foster highly specialized professionals and researchers who, by creating intelligent systems, can lead the research and development of new computer systems to support people’s day-to-day activities. In order to develop high-performance systems that can cope with our changing world, we offer education and research on highly efficient algorithms based on graph theory, which rapidly solve problems that are common in the real world, including optimization and tallying, intelligent information processing systems that efficiently process sound, optics, images, etc. by focusing on the characteristics of their qualities and sense of hearing, and intelligent systems based on modelling a target. We also give our students the capacity to design these systems.

社会基盤・環境工学分野Social Infrastructure and Environmental Engineering Area

社会基盤・環境工学分野では,社会基盤・環境工学に関する専門分野への見識を深めるとともに,人と社会・産業をつなぐ社会基盤・環境システムの創成のため,建設工学,環境工学,防災工学の各領域における最新の学術研究成果に基づく工学分野の高度な教育研究を行います。課題の設定,全体構想の立案,研究の遂行と解析に独自性を発揮できる能力を培い,今後社会的要請が高まると考えられる建設,環境,防災の観点を視野に入れた社会基盤の整備において指導的な役割を果たす研究者あるいは高度専門技術者を養成します。建設工学領域では,地質及び土質の特性の解明,斜面安定の評価手法の開発,構造物の動的応答解析及び合成構造物の解析手法,耐震設計手法の開発,耐久性・経済性に優れた建設材料の開発,建設廃棄物の有効利用方法の開発等に関する社会基盤を構築するための教育研究を行います。防災工学領域では,地盤の振動特性解析,活断層の構造形態解析,地震・火山噴火・斜面崩壊・津波・洪水などの発生メカニズムの解明や防災システムの開発等に関する安全・安心な社会を構築するための教育研究を行います。環境工学領域では,生態系の保全を視野に入れた地域環境の創出のための環境計画,都市再生計画手法の体系化,水質や土壌の汚染制御と環境保全・修復技術の開発,高齢者や障がい者などに優しく安全な地域や街づくりのためのユニバーサルデザインや交通システムの計画・管理手法の開発等に関する持続可能な環境や社会を構築するための教育研究を行います。

In the Social Infrastructure and Environmental Engineering Area, we offer deeper insights into specialized fields relating to social infrastructure and environmental engineering, and provide high-level education and research in the field of engineering based on the latest academic research results in the areas of Construction Engineering, Environmental Engineering, and Disaster Prevention Engineering, in order to construct social infrastructure and environmental systems that connect people to society and industry. We cultivate the ability to identify tasks, formulate complete plans, and display originality in carrying out and analyzing research; we also foster highly specialized engineers and researchers who will play leading roles in maintaining social infrastructure, taking into consideration the viewpoints of construction, the environment and disaster prevention, which we believe will be requested more and more in the future.In Construction Engineering, we offer education and research that enables students to construct social infrastructure, linked to the clarification of the characteristics of geological features and soil quality, the development of evaluation methods for slope stability, the development of methods for analyzing the dynamic response of structures, analyzing composite structures and measuring earthquake resistance, the development of building materials excellent for durability and economy, and the development of methods to effectively use construction waste.In Disaster Prevention Engineering, we provide education and research that will enable students to build a safe, secure society, linked to the analysis of the characteristics of ground vibrations, the analysis of the structural form of active faults, the clarification of generation mechanisms – including those of earthquakes, volcanic eruptions, slope failures, tsunamis, and floods – and the development of disaster prevention systems.In Environmental Engineering, we offer education and research so that our students can build a sustainable environment and society linked to the production of environmental plans to create local environments that take into account ecosystem preservation, the systemization of urban regeneration planning methods, the development of pollution control for water quality and the soil, the development of technology for environmental conservation and restoration, and the development of planning and management methods for transportation systems, and universal design, which will enable the creation of safe localities and streets that are friendly to the elderly and the disabled.

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