Kooperativer Bibliotheksverbund

UID:

Umfang: 1 Online-Ressource (XVIII, 422 Seiten) , llustrationen, Diagramme

ISBN: 9783966270175 , 9783966270182

Inhalt: Die zeitnahe, transparente und nachhaltige Verbreitung nachprüfbarer wissenschaftlicher Ergebnisse ist eine der wesentlichen Anforderungen an die wissenschaftliche Kommunikation und Infrastruktur. Open Access, also die offene und kostenfreie Nutzung von wissenschaftlicher Literatur, ist hierfür die Grundvoraussetzung. Hochschulen und Universitäten sind in der Regel die Institutionen, an denen Wissenschaftler neue Forschungsergebnisse erzeugen und zur Veröffentlichung als Buch vorbereiten. Neben klassischen Wissenschaftsverlagen veröffentlichen daher immer mehr Hochschulverlage wissenschaftliche Publikationen. Das vorliegende Handbuch beschreibt einen nachhaltigen, allgemeingültigen State-of-the-Art-Workflow zur Herstellung und Distribution von akademischen Büchern, der es Hochschulen und Universitäten ermöglicht, bei weitest möglicher Verbreitung, Sichtbarkeit und Zugänglichkeit eigene Forschungsarbeiten und Graduierungsschriften in digitaler Form im Open Access und als gedrucktes Buch zu veröffentlichen. Dieses Workflow-Modell wird anhand ausgewählter Fallbeispiele als Proof of Concept demonstriert und spiegelt den aktuellen Stand der derzeit im Verlagsbereich technischen und wirtschaftlichen Möglichkeiten wider. Anhand der Fallbeispiele wurden zudem der Zeit-, Kosten- und Personalaufwand erfasst, sodass anderen Hochschulen und Universitäten Anhaltspunkte für nötige Investitionen bei der Gründung und dem Betrieb eigener OA-Hochschulverlage gegeben werden.

Anmerkung: Literaturverzeichnis: Seite 369-375

Weitere Ausg.: ISBN 9783966270168

Weitere Ausg.: ISBN 3966270161

Weitere Ausg.: ISBN 9783966270151

Weitere Ausg.: Erscheint auch als Druck-Ausgabe Böhm, David Open-Access-Publikationsworkflow für akademische Bücher Leipzig : Open-Access-Hochschulverlag, Hochschule für Technik, Wirtschaft und Kultur Leipzig, 2020 ISBN 9783966270151

Weitere Ausg.: ISBN 9783966270168

Sprache: Deutsch

Fachgebiete: Allgemeines

Schlagwort(e): Open Access ; Arbeitsablauf ; Veröffentlichung ; Universitätsverlag ; Open Access ; Wissenschaftskommunikation ; Wissenschaftliche Literatur ; Bibliothek ; Handbooks and manuals

DOI: 10.33968/9783966270175-00

URL: Volltext  (kostenfrei)

URL: Volltext  (kostenfrei)

URL: FULL

Mehr zum Autor: Böhm, David

Mehr zum Autor: Grossmann, Alexander

Mehr zum Autor: Reiche, Michael 1964-

Mehr zum Autor: Schrader, Antonia

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Umfang: 58 Seiten , Illustrationen

Ausgabe: 1. Auflage

ISBN: 9783751200103

Serie: Emmi & Einschwein

Inhalt: Einschwein hat keine Lust lesen zu üben, doch in der Bibliothek erlebt er so tolle Dinge mit dem Buchodil, der Lesekatze und dem papierdünnen Fabeltier Platti, dass er nach und nach doch Interesse am Lesen gewinnt. Ab 6.

Sprache: Deutsch

UID:

Umfang: 61 pages : , illustrations ; , 21 × 29.7 cm.

Inhalt: AI-GENERATED ABSTRACT: Abstract: The build environment has a significant impact on the climate crisis, consuming large amounts of resources and contributing to energy consumption and CO2 emissions. The linear approach to architecture and interior design, with a take-make-waste attitude, exacerbates these negative effects. Transitioning to a circular economy is essential to address these issues by keeping materials in a closed-loop system and reducing waste. This thesis focuses on the regeneration of existing factory buildings within a circular design framework, primarily in the context of interior architecture. The research aims to identify circular design principles and explore their application in regenerating factory buildings. The methodology includes a systematic review of literature on the circular economy, analysis of circular design principles, consultation with leading architectural studios, and a case study of a regenerated factory building. The findings contribute to the understanding of circular design principles in the context of building regeneration and offer insights for sustainable practices in the built environment. Keywords: circular economy, regeneration, factory buildings, interior architecture, circular design principles.

Anmerkung: DISSERTATION NOTE: Bachelor of Arts thesis in Interior Architecture/Interior Design, Berlin International University of Applied Sciences, 2022. , MACHINE-GENERATED CONTENTS NOTE: Table of Contents 1. Introduction 1.1 Background and Relevance 1.2 Research design and methodology 2. Circular Economy 2.1 Definition 2.2 Origin and Enabler 3. Circular Design Framework 3.1 Circular building design principles 3.1.1 Build in layers 3.1.2 Build nothing 3.1.3 Build for long term value 3.1.3.1 Design for longevity 3.1.3.2 Increasing the building utilization 3.1.3.3 Design for Adaptability 3.1.3.4 Design for Disassembly 3.1.4 Build with the right material 3.1.4.1 Reclaimed and recycled material 3.1.4.2 Biobased material 3.1.5 Build efficiently 4. Case Study: Existing Factory 4.1 CRCLR House, Berlin Neukölln 5. Conclusion Design Project 5.1 Location Analysis 5.2 Design Proposal and Intervention 5.3 Conclusion Design Project References Bibliography

Sprache: Unbestimmte Sprache

Schlagwort(e): Academic theses

URL: FULL

UID:

Umfang: 61 pages : , illustrations ; , 21 × 29.7 cm.

Inhalt: AI-GENERATED ABSTRACT: Abstract: The build environment has a significant impact on the climate crisis, consuming large amounts of resources and contributing to energy consumption and CO2 emissions. The linear approach to architecture and interior design, with a take-make-waste attitude, exacerbates these negative effects. Transitioning to a circular economy is essential to address these issues by keeping materials in a closed-loop system and reducing waste. This thesis focuses on the regeneration of existing factory buildings within a circular design framework, primarily in the context of interior architecture. The research aims to identify circular design principles and explore their application in regenerating factory buildings. The methodology includes a systematic review of literature on the circular economy, analysis of circular design principles, consultation with leading architectural studios, and a case study of a regenerated factory building. The findings contribute to the understanding of circular design principles in the context of building regeneration and offer insights for sustainable practices in the built environment. Keywords: circular economy, regeneration, factory buildings, interior architecture, circular design principles.

Anmerkung: DISSERTATION NOTE: Bachelor of Arts thesis in Interior Architecture/Interior Design, Berlin International University of Applied Sciences, 2022. , MACHINE-GENERATED CONTENTS NOTE: Table of Contents 1. Introduction 1.1 Background and Relevance 1.2 Research design and methodology 2. Circular Economy 2.1 Definition 2.2 Origin and Enabler 3. Circular Design Framework 3.1 Circular building design principles 3.1.1 Build in layers 3.1.2 Build nothing 3.1.3 Build for long term value 3.1.3.1 Design for longevity 3.1.3.2 Increasing the building utilization 3.1.3.3 Design for Adaptability 3.1.3.4 Design for Disassembly 3.1.4 Build with the right material 3.1.4.1 Reclaimed and recycled material 3.1.4.2 Biobased material 3.1.5 Build efficiently 4. Case Study: Existing Factory 4.1 CRCLR House, Berlin Neukölln 5. Conclusion Design Project 5.1 Location Analysis 5.2 Design Proposal & Intervention 5.3 Conclusion Design Project References Bibliography

Sprache: Unbestimmte Sprache

Schlagwort(e): Academic theses

URL: FULL

UID:

ISSN: 0006-4416

In: Blätter für deutsche und internationale Politik, Berlin : Blätter-Verl.-Ges., 1956, 66(2021), 3, Seite 51-63, 0006-4416

In: volume:66

In: year:2021

In: number:3

In: pages:51-63

Sprache: Deutsch

Mehr zum Autor: Brumlik, Micha 1947-

Mehr zum Autor: Boehm, Omri 1979-

Mehr zum Autor: Tsimerman, Mosheh 1943-

Mehr zum Autor: Stein, Shimon 1948-

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ISSN: 1430-175X

In: Internationale Politik, Berlin : Deutsche Gesellschaft für Auswärtige Politik, 1995, März/April 2021, Nr. 2, 76. Jahr, Seite 83-86, 1430-175X

In: volume:76

In: year:2021

In: number:2

In: pages:83-86

Sprache: Deutsch

Mehr zum Autor: Böhm, Andrea 1961-

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Umfang: 1 online resource (411 pages)

Ausgabe: 1st ed.

ISBN: 9783030621360

Anmerkung: Intro -- Preface -- Table of Contents -- 1 CrESt Use Cases -- 1.1 Introduction -- 1.2 Vehicle Platooning -- 1.3 Adaptable and Flexible Factory -- 1.4 Autonomous Transport Robots -- 2 Engineering of Collaborative Embedded Systems -- 2.1 Introduction -- 2.2 Background -- 2.3 Collaborating Embedded Systems -- 2.3.1 Collaborative and Collaborating Systems -- 2.3.2 Goals of System Networks -- 2.3.3 Coordination in System Networks -- 2.3.4 Dynamics in System Networks -- 2.3.5 Functions -- 2.4 Problem Dimensions of Collaborative Embedded Systems -- 2.4.1 Challenges Related to Collaboration -- 2.4.2 Challenges Related to Dynamics -- 2.5 Application in the Domains "Cooperative Vehicle Automation" and "Industry 4.0" -- 2.5.1 Challenges in the Application Domain "Cooperative Vehicle Automation" -- Collaboration -- Dynamics -- 2.5.2 Challenges in the Application Domain "Industry 4.0" -- Collaboration -- Dynamics -- 2.6 Concepts and Methods for the Development of Collaborative Embedded Systems -- 2.6.1 Enhancements Regarding SPES2020 and SPES_XT -- 2.6.2 Collaboration -- Goals -- Functions and Behavior -- Architecture and Structure -- Communication -- 2.6.3 Dynamics -- Goals -- Functions and Behavior -- Architecture and Structure -- Context -- Uncertainty -- 2.7 Conclusion -- 2.8 Literature -- 2.9 Appendix -- 3 Architectures for Flexible Collaborative Systems -- 3.1 Introduction -- 3.2 Designing Reference Architectures -- 3.2.1 Method for Designing Reference Architectures -- 3.2.2 Application Example: Reference Architecture for Adaptable and Flexible Factories -- 3.3 Reference Architecture for Operator Assistance Systems -- 3.3.1 Simulation-Based Operator Assistance -- 3.3.2 Design Decisions -- 3.3.3 Technical Reference Architecture -- 3.3.4 Workflow of Services and Data Flow -- 3.3.5 Application Example for an Adaptable and Flexible Factory , 3.4 Checkable Safety Cases for Architecture Design -- 3.4.1 Checkable Safety Case Models - A Definition -- 3.4.2 Checkable Safety Case Patterns -- 3.4.3 An Example of Checkable Safety Case Patterns -- 3.5 Conclusion -- 3.6 Literature -- 4 Function Modeling for Collaborative Embedded Systems -- 4.1 Introduction -- 4.2 Methodological Approach -- 4.3 Background -- 4.4 Metamodel for Functions of CESs and CSGs -- 4.4.1 Systems, CESs, and CSGs -- 4.4.2 Functions -- 4.4.3 Goal Contribution and Fulfillment -- 4.4.4 Roles -- 4.4.5 Context and Adaptivity -- 4.5 Evaluation of the Metamodel -- 4.5.1 Abstraction -- 4.5.2 Relationships between Functions -- 4.5.3 Openness and Dynamicity -- 4.5.4 Goal Contributions -- 4.5.5 Relationships Between Functions and Systems -- 4.5.6 Input/Output Compatibility -- 4.5.7 Runtime Restructuring -- 4.6 Application of the Metamodel -- 4.6.1 Example from the Adaptable and Flexible Factory -- 4.6.2 Modeling of Goals for Transport Robots -- 4.7 Related Work -- 4.8 Conclusion -- 4.9 Literature -- 5 Architectures for Dynamically Coupled Systems -- 5.1 Introduction -- 5.2 Specification Modeling of the Behavior of Collaborative System Groups -- 5.3 Modeling CES Functional Architectures -- 5.3.1 Scenario -- 5.3.2 Modelling -- 5.3.3 Analysis -- 5.4 Extraction of Dynamic Architectures -- 5.4.1 Methods -- 5.4.2 Software Product Line Engineering -- 5.4.3 Product-Driven Software Product Line Engineering -- 5.4.4 Family Mining - A Method for Extracting Reference Architectures from Model Variants -- 5.4.5 Summary -- 5.5 Functional Safety Analysis (Online) -- 5.5.1 Functional Testing -- 5.5.2 Communication Errors -- 5.6 Conclusion -- 5.7 Literature -- 6 Modeling and Analyzing Context-Sensitive Changes during Runtime -- 6.1 Introduction and Motivation -- 6.2 Solution Concept -- 6.3 Ontology and Modeling -- 6.3.1 Ontology Building , 6.3.2 Capability Modeling -- 6.3.3 Variability Modeling for Context-Sensitive Reconfiguration -- 6.3.4 Scenario-Based Modeling -- 6.4 Model Integration and Execution -- 6.4.1 Model Generation for Simulation Models -- Model Generation via Knowledge Graph -- Application to a Real Production System -- 6.4.2 Capability Matching -- 6.5 Conclusion -- 6.6 Literature -- 7 Handling Uncertainty in Collaborative Embedded Systems Engineering -- 7.1 Uncertainty in Collaborative Embedded Systems -- 7.1.1 Conceptual Ontology for Handling Uncertainty -- 7.1.2 Different Kinds of Uncertainty -- 7.2 Modeling Uncertainty -- 7.2.1 Orthogonal Uncertainty Modeling -- Modeling Concepts and Notation -- Example -- 7.2.2 Modeling Uncertainty in Traffic Scenarios -- Modeling Traffic Scenarios for CSGs -- Behavioral Uncertainty Modeling -- Risk Assessment -- 7.3 Analyzing Uncertainty -- 7.3.1 Identifying Epistemic Uncertainties -- Uncertainty Sources at the Type Level -- Uncertainty Sources at the Instance Level -- EURECA -- 7.3.2 Assessing Data-Driven Uncertainties -- Three Types of Uncertainty Sources -- Managing Uncertainty during Operation -- Uncertainty Wrapper - Architecture and Application -- Uncertainty Wrappers - Limitations and Advantages -- 7.4 Conclusion -- 7.5 Literature -- 8 Dynamic Safety Certification for Collaborative Embedded Systems at Runtime -- 8.1 Introduction and Motivation -- 8.2 Overview of the Proposed Safety Certification Concept -- 8.3 Assuring Runtime Safety Based on Modular Safety Cases -- 8.3.1 Modeling CESs and their Context -- Modeling the Context -- Content Ontology -- Modeling Context in the Adaptable Factory -- 8.3.2 Runtime Uncertainty Handling -- Concept Overview -- Development of a U-Map for the Adaptable Factory -- 8.3.3 Runtime Monitoring of CESs and their Context -- Meta-model SQUADfps -- Case Study Example , 8.3.4 Integrated Model-Based Risk Assessment -- 8.3.5 Dynamic Safety Certification -- 8.4 Design and Runtime Contracts -- 8.4.1 Design-Time Approach for Collaborative Systems -- Creating the CSG Specification -- Safety-Relevant Activities -- 8.4.2 Contracts Concept -- 8.4.3 Runtime Evaluation of Safety Contracts -- Simulative Approach for Validation of Safety Contracts -- Case Study: Vehicle Platoon Example -- 8.5 Conclusion -- 8.6 Literature -- 9 Goal-Based Strategy Exploration -- 9.1 Introduction -- 9.2 Goal Modeling for Collaborative System Groups -- 9.3 Goal-Based Strategy Development -- 9.4 Goal Operationalization (KPI Development) -- 9.5 Modeling Methodology for Adaptive Systems with MATLAB/Simulink -- 9.6 Collaboration Framework for Goal-Based Strategies -- 9.6.1 Fleet Management in Collaborative Resource Networks -- 9.6.2 Collaboration Framework -- 9.6.3 Collaboration Design in Decentralized Fleet Management -- 9.7 Conclusion -- 9.8 Literature -- 10 Creating Trust in Collaborative Embedded Systems -- 10.1 Introduction -- 10.2 Building Trust during Design Time -- Testing framework for CSGs -- Model -- View -- Controller -- 10.3 Building Trust during Runtime -- 10.4 Monitoring Collaborative Embedded Systems -- Runtime Monitoring -- Runtime Monitoring of Collaborative System Groups -- Distributedness: -- Embeddedness: -- Runtime Monitoring of Interaction Protocols -- Monitoring Functional Correctness -- Agreement: -- Existence: -- Maximum: -- Monitoring Correct Timing Behavior -- U -- Ut -- 10.5 Conclusion -- 10.6 Literature -- 11 Language Engineering for Heterogeneous Collaborative Embedded Systems -- 11.1 Introduction -- 11.2 MontiCore -- 11.3 Language Components -- 11.4 Language Component Composition -- 11.5 Language Product Lines -- 11.6 Conclusion -- 11.7 Literature , 12 Development and Evaluation of Collaborative Embedded Systems using Simulation -- 12.1 Introduction -- 12.1.1 Motivation -- 12.1.2 Benefits of Using Simulation -- 12.2 Challenges in Simulating Collaborative Embedded Systems -- 12.2.1 Design Time Challenges -- 12.2.2 Runtime Challenges -- 12.3 Simulation Methods -- 12.4 Application -- 12.5 Conclusion -- 12.6 Literature -- 13 Tool Support for CoSimulation-Based Analysis -- 13.1 Introduction -- 13.2 Interaction of Different Simulations -- 13.3 General Tool Architecture -- 13.4 Implementing Interoperability for Co-Simulation -- 13.5 Distributed Co-Simulation -- 13.6 Analysis of Simulation Results -- 13.7 Conclusion -- 13.8 Literature -- 14 Supporting the Creation of Digital Twins for CESs -- 14.1 Introduction -- 14.2.1 Demonstration -- Automotive Smart Ecosystems -- Smart Grids -- 14.2 Building Trust through Digital Twin Evaluation -- 14.3 Conclusion -- 14.4 Literature -- 15 Online Experiment-Driven Learning and Adaptation -- 15.1 Introduction -- 15.2 A Self-Optimization Approach for CESs -- 15.3 Illustration on CrowdNav -- 15.4 Conclusion -- 15.5 Literature -- 16 Compositional Verification using Model Checking and Theorem Proving -- 16.1 Introduction -- 16.2 Approach -- 16.3 Example -- 16.3.1 Specification -- 16.3.2 Verification -- 16.4 Conclusion -- 16.5 Literature -- 17 Artifact-Based Analysis for the Development of Collaborative Embedded Systems -- 17.1 Introduction -- 17.2 Foundations -- UML/P -- Class Diagrams in UML/P -- Object Diagrams in UML/P -- OCL -- 17.3 Artifact-Based Analysis -- Artifact Model Creation -- Specification of Artifact Data Analysis -- Artifact-Based Analyses -- 17.4 Artifact Model for Systems Engineering Projects with Doors NG and Enterprise Architect -- 17.4.1 Artifact Modeling of Doors NG and Enterprise Architect , 17.4.2 Static Extractor for Doors NG and Enterprise Architect Exports

Weitere Ausg.: Print version Böhm, Wolfgang Model-Based Engineering of Collaborative Embedded Systems Cham : Springer International Publishing AG,c2020 ISBN 9783030621353

Sprache: Englisch

Schlagwort(e): Electronic books

URL: Full-text  ((OIS Credentials Required))