標(biāo)題: Titlebook: Handbook of Engineering Systems Design; Anja Maier,Josef Oehmen,Pieter E. Vermaas Living reference work 20200th edition Designing Enginee [打印本頁] 作者: Hazardous 時(shí)間: 2025-3-21 16:23
書目名稱Handbook of Engineering Systems Design影響因子(影響力)
書目名稱Handbook of Engineering Systems Design影響因子(影響力)學(xué)科排名
書目名稱Handbook of Engineering Systems Design網(wǎng)絡(luò)公開度
書目名稱Handbook of Engineering Systems Design網(wǎng)絡(luò)公開度學(xué)科排名
書目名稱Handbook of Engineering Systems Design被引頻次
書目名稱Handbook of Engineering Systems Design被引頻次學(xué)科排名
書目名稱Handbook of Engineering Systems Design年度引用
書目名稱Handbook of Engineering Systems Design年度引用學(xué)科排名
書目名稱Handbook of Engineering Systems Design讀者反饋
書目名稱Handbook of Engineering Systems Design讀者反饋學(xué)科排名
作者: 釘牢 時(shí)間: 2025-3-21 23:44
History of Engineering Systems Design Research and Practice,he twentieth century. Concurrently, there was the emergence in the scientific community of the notion of a system, which led to new scientific studies, from systems analysis and cybernetics to network science and soft systems methodology. These various strands have come together at the beginning of 作者: 銼屑 時(shí)間: 2025-3-22 02:24 作者: Enervate 時(shí)間: 2025-3-22 06:13 作者: 獸群 時(shí)間: 2025-3-22 11:04
The Evolution of Complex Engineering Systems,can accommodate new demands. Different approaches have been developed to manage and predict engineering changes. Understanding and managing change is particularly important for complex engineering systems, which often constitute large-scale long-term investments and are expected to keep operating wh作者: 邪惡的你 時(shí)間: 2025-3-22 14:03
Technical and Social Complexity,exity drivers, we argue for a shift in perspective, from . to .. Moreover, in most complex socio-technical engineering systems, managing complexity requires adopting a lens of system . – as opposed to conventional engineering design lens – whose goal is to steer the emergent behaviour of the system 作者: 專心 時(shí)間: 2025-3-22 20:11 作者: 高腳酒杯 時(shí)間: 2025-3-22 23:58
Dynamics and Emergence: Case Examples from Literature,s through their applications in six case examples. Six studies conducted by researchers around the world are selected, representing a portfolio of cases studied with multiple theoretical foundations, levels of scope, application domains of engineering systems design, phenomena of emergence, and mode作者: 解決 時(shí)間: 2025-3-23 03:34
Properties of Engineering Systems, pursuit are discussed. Design principles serve as prescriptions for specific design interventions that enable the design and evolution of an engineering system that possesses the desirable system properties over its lifespan.作者: extinct 時(shí)間: 2025-3-23 07:15 作者: 清楚說話 時(shí)間: 2025-3-23 13:05 作者: Trypsin 時(shí)間: 2025-3-23 15:43
Data-Driven Preference Modelling in Engineering Systems Design,ed customer preference modelling techniques are identified. This chapter shows how such limitations can be overcome by modelling heterogeneous customer preferences and choice behaviours based on the science of complex networks and theories from the social sciences. Two case studies on vehicle system作者: 管理員 時(shí)間: 2025-3-23 18:29 作者: certain 時(shí)間: 2025-3-24 00:49 作者: appall 時(shí)間: 2025-3-24 04:11
Designing for Emergent Safety in Engineering Systems,dback, feedforward, positive, and negative) and, especially, interrelated loops. The chapter explores also the realm of security threats due to malign actions that can trigger safety-threatening events. And finally it gives general guidance for avoiding and eliminating safety hazards when designing 作者: extrovert 時(shí)間: 2025-3-24 08:19
Engineering Systems in Flux: Designing and Evaluating Interventions in Dynamic Systems,on. This chapter reviews these strategies, discusses how they relate to systems engineering methodologies, and then highlights exploratory modeling and participatory modeling as methods for ex ante evaluation of interventions in dynamic engineering systems.作者: 帽子 時(shí)間: 2025-3-24 12:14 作者: BLAND 時(shí)間: 2025-3-24 16:39 作者: CAJ 時(shí)間: 2025-3-24 20:37
oach requires the (re)designing of engineering systems that take into account the shifting dynamics of human behaviour, the influence of global stakeholders, and the need for system integration.??.The text is a978-3-030-46054-9作者: 黑豹 時(shí)間: 2025-3-24 23:10 作者: 大火 時(shí)間: 2025-3-25 07:13
https://doi.org/10.1007/978-3-7091-5412-0he twentieth century. Concurrently, there was the emergence in the scientific community of the notion of a system, which led to new scientific studies, from systems analysis and cybernetics to network science and soft systems methodology. These various strands have come together at the beginning of 作者: 施舍 時(shí)間: 2025-3-25 07:35
Werner Nothdurft,Thomas Spranz-Fogasy the younger generation is successfully increasing its pressure on the incumbent world and industry leaders..But how can engineering systems interpret these agendas and make a contribution to sustainability transition? What is the potential of taking a socio-technical holistic view on large and comp作者: 賭博 時(shí)間: 2025-3-25 14:17
https://doi.org/10.1007/978-3-531-94074-8L, (eds) Germany and the World 2030. What will change. How we must act. Econ Publ, Berlin, 2018). This will have a significant impact on the design of tomorrow’s engineering systems (de Weck et al. Engineering systems: meeting human needs in a complex technological world. MIT Press, Cambridge, 2011)作者: Gerontology 時(shí)間: 2025-3-25 19:10
Rudolph Bauer,Anna-Maria Thr?nhardtcan accommodate new demands. Different approaches have been developed to manage and predict engineering changes. Understanding and managing change is particularly important for complex engineering systems, which often constitute large-scale long-term investments and are expected to keep operating wh作者: zonules 時(shí)間: 2025-3-25 20:31 作者: STANT 時(shí)間: 2025-3-26 02:00
,50 Adressen von Verb?nden in Deutschland,ance. We differentiate for each level of uncertainty between two levels of value diversity: (1) primarily commensurate values (i.e. agreement on core values by critical stakeholders) and (2) primarily incommensurate values (i.e. no agreement on core values). The managerial practices we discuss are “作者: LUMEN 時(shí)間: 2025-3-26 06:20
Charakteristika von Wirtschaftsverb?ndens through their applications in six case examples. Six studies conducted by researchers around the world are selected, representing a portfolio of cases studied with multiple theoretical foundations, levels of scope, application domains of engineering systems design, phenomena of emergence, and mode作者: 高歌 時(shí)間: 2025-3-26 10:09
https://doi.org/10.1007/978-3-663-14538-7 pursuit are discussed. Design principles serve as prescriptions for specific design interventions that enable the design and evolution of an engineering system that possesses the desirable system properties over its lifespan.作者: 細(xì)微的差異 時(shí)間: 2025-3-26 15:13 作者: 背叛者 時(shí)間: 2025-3-26 20:20 作者: 猛烈責(zé)罵 時(shí)間: 2025-3-26 21:32
,Deutung und Auswertung der Me?ergebnisse,ed customer preference modelling techniques are identified. This chapter shows how such limitations can be overcome by modelling heterogeneous customer preferences and choice behaviours based on the science of complex networks and theories from the social sciences. Two case studies on vehicle system作者: 有幫助 時(shí)間: 2025-3-27 04:24
,Durchführung der Untersuchungen, create and sustain change in a systemic world, designers need to consider combinations of interventions across multiple levels that work together in both the short and longer term. We encapsulate this into four main points of guidance, illustrated by examples from health behaviour, sustainable beha作者: Projection 時(shí)間: 2025-3-27 08:37
,Methoden der Korrosionsprüfung,ties include design for quality, design for changeability, and, more generally, design for X. To support both top-down functional design and design for emergent properties, commonly used modeling and simulation approaches, and optimization-based approaches are discussed. The chapter discusses challe作者: 廢止 時(shí)間: 2025-3-27 11:40 作者: Conducive 時(shí)間: 2025-3-27 15:28 作者: Instantaneous 時(shí)間: 2025-3-27 18:45
https://doi.org/10.1007/978-3-663-07505-9g systems. Section “.” discusses the finer details of systems testing by presenting current challenges for testing engineering systems, suitable testing approaches, and the roll of test planning (design of experiments) in engineering systems development. Section “.” of this chapter presents an examp作者: 獸群 時(shí)間: 2025-3-28 01:16
Fasermischungen in Garnen und Zwirnen,pes of measurement that can be applied to evaluating such interventions. More specifically, it contrasts experimental, data-driven, and model-based approaches. It recognizes that only the last of these is appropriate for interventions that change system structure. Consequently, the chapter concludes作者: Amplify 時(shí)間: 2025-3-28 03:50
Living reference work 20200th editional system and a responsibility for global sustainability goals.? The new paradigm and approach requires the (re)designing of engineering systems that take into account the shifting dynamics of human behaviour, the influence of global stakeholders, and the need for system integration.??.The text is a作者: 不妥協(xié) 時(shí)間: 2025-3-28 07:24
https://doi.org/10.1007/978-3-030-46054-9Designing Engineering Systems Interventions; Engineering Systems; Engineering Systems Perspective; desi作者: Fecal-Impaction 時(shí)間: 2025-3-28 13:15 作者: ERUPT 時(shí)間: 2025-3-28 15:30
http://image.papertrans.cn/h/image/421255.jpg作者: follicular-unit 時(shí)間: 2025-3-28 19:16
Living reference work 20200th editioncusses the design, management and enabling policy of engineering systems. It contains explorations of core themes including technical and (socio-) organisational complexity, human behaviour and uncertainty. The text includes chapters on the education of future engineers, the way in which interventio作者: 半導(dǎo)體 時(shí)間: 2025-3-29 03:00 作者: GULLY 時(shí)間: 2025-3-29 04:10 作者: Inordinate 時(shí)間: 2025-3-29 09:24
https://doi.org/10.1007/978-3-663-07507-3 to engineering systems research. Our hope is that by providing a common framework for interpreting research results across diverse methods, more engineering systems researchers will feel comfortable building on results obtained through diverse approaches.作者: 窩轉(zhuǎn)脊椎動(dòng)物 時(shí)間: 2025-3-29 14:54
Design Perspectives, Theories, and Processes for Engineering Systems Design,age-based, agile, and set-based models and many more, is provided. It is explained how each of the discussed approaches offers valuable insights that help to address different aspects of complex systems design. The evolution of the approaches reflects the evolving recognition of users and context when designing engineering systems.作者: aerobic 時(shí)間: 2025-3-29 19:04
Research Methods for Supporting Engineering Systems Design, to engineering systems research. Our hope is that by providing a common framework for interpreting research results across diverse methods, more engineering systems researchers will feel comfortable building on results obtained through diverse approaches.作者: 破布 時(shí)間: 2025-3-29 22:45 作者: Longitude 時(shí)間: 2025-3-30 01:09 作者: nuclear-tests 時(shí)間: 2025-3-30 07:13
Lexical Knowledge Base and Corpus,th technical and human terms. Engineering systems evolve over time, and uncertainty over time plays a decisive role. Perspectives on design, design theories, and design processes can be used to guide and support designers of engineering systems. This chapter provides an introduction to several well-作者: 確定無疑 時(shí)間: 2025-3-30 11:45
Werner Nothdurft,Thomas Spranz-Fogasyalth, we have recognised that humankind is “out of planetary compliance”. Or in other words, we are borrowing from next generations, each and every day, with the direct negative effects of raising atmospheric temperatures (global warming), poisoning of our land and waterways, and threatening the bio作者: 煤渣 時(shí)間: 2025-3-30 16:06
https://doi.org/10.1007/978-3-531-94074-8inating possibilities and will change the world of tomorrow. It is important to tap the associated potentials for innovation in order to maintain competitiveness and secure future success. However, studies show that many companies still have major problems in shaping the digital transformation. The 作者: Provenance 時(shí)間: 2025-3-30 18:47 作者: lipoatrophy 時(shí)間: 2025-3-30 21:30
https://doi.org/10.34156/9783791053943trying to find universal definitions and measures. Focusing on the key drivers enables us to identify and evaluate system-level trade-offs and equip us with leverage points that can enable engineering methods to manage system complexity. We will discuss two of the main drivers of complexity: increas作者: CLAIM 時(shí)間: 2025-3-31 03:25
,50 Adressen von Verb?nden in Deutschland,llary of uncertainty,?is understood as the effect of uncertainty on objectives. When designing engineering systems, you cannot not manage risk – even ignoring risk equates to a decision to accept it. Engineering systems are characterised by long life cycles, changing operational environments, and ev作者: d-limonene 時(shí)間: 2025-3-31 06:46
Charakteristika von Wirtschaftsverb?ndenrnance of complex engineering systems. It is almost impossible to effectively model emergence within the dynamics of systems, due to the obscurity of its nature and imperfection of our information on its relational systemic interactions. Thus, paying attention to basic meta-questions about emergent 作者: 琺瑯 時(shí)間: 2025-3-31 11:31
https://doi.org/10.1007/978-3-663-14538-7This chapter focuses specially on desired engineering system properties and their relevance to designing effective interventions that ultimately result in sustainable value delivery to society. Desired properties, as discussed in this chapter, are higher-order properties, emerging as a consequence o作者: stress-response 時(shí)間: 2025-3-31 14:44
https://doi.org/10.1007/978-3-663-11719-3 complexity in their physical manifestations and the elaborate processes, usually operated by people, needed to realise, use, and support such systems through life. Although engineering design tends to focus on technical aspects of these physical manifestations, it is the delivery of the associated 作者: CANDY 時(shí)間: 2025-3-31 21:12
Verbessertes virtuelles PrototypingSystem architecture is critical in designing engineering systems as it is a focal point where novel designs are discussed, often in the form of integrating new technologies into existing system architectures. A key aspect of addressing system architecture is identifying, modeling, and managing criti作者: DECRY 時(shí)間: 2025-3-31 21:47
,Deutung und Auswertung der Me?ergebnisse, the need for modelling customer preferences in engineering systems design for understanding the interactions among multiple stakeholders in a complex design ecosystem. This chapter starts with an introduction to multi-stakeholder decision-making in complex engineering systems and existing research 作者: 遺留之物 時(shí)間: 2025-4-1 05:38
,Durchführung der Untersuchungen,igners today, from fields spanning the natural, social, behavioural, health, and technical sciences. This chapter provides an overview and synthesis of approaches, as well as guidance through this landscape for designers. Literature is reviewed from two perspectives: (i) ‘technology-first’, where te作者: 整理 時(shí)間: 2025-4-1 10:04 作者: grovel 時(shí)間: 2025-4-1 12:15 作者: colony 時(shí)間: 2025-4-1 18:10
https://doi.org/10.1007/978-3-663-07504-2d socio-technical artefact should improve system performance not only under present conditions, but it must also be functional when conditions change, be it autonomously or due to interventions performed by others, and (2) the actual intervention of implementing the artefact should be planned such t
