01777nam 2200457z- 450 9910346779803321202102111000047227(CKB)4920000000100725(oapen)https://directory.doabooks.org/handle/20.500.12854/44598(oapen)doab44598(EXLCZ)99492000000010072520202102d2015 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierA Decentralized Control Strategy for High Density Material Flow Systems with Automated Guided VehiclesKIT Scientific Publishing20151 online resource (X, 160p. p.)Wissenschaftliche Berichte des Instituts für Fördertechnik und Logistiksysteme des Karlsruher Instituts für Technologie3-7315-0389-1 This work presents a universal decentralized control strategy for grid-based high-density material flow systems with automated guided vehicles and gives insights into the system behavior as well as the solution quality.Technology: general issuesbicsscautomated guided vehiclescompactFahrerlose Transportsystemehigh densityhochdichtkompaktLagersystemematerial flow systemsMaterialflusssystemestorage systemsTechnology: general issuesSchwab Melanieauth1329326BOOK9910346779803321A Decentralized Control Strategy for High Density Material Flow Systems with Automated Guided Vehicles3039431UNINA03270nam 2200409z- 450 991034675700332120210211(CKB)4920000000094144(oapen)https://directory.doabooks.org/handle/20.500.12854/47136(oapen)doab47136(EXLCZ)99492000000009414420202102d2018 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierEvolution of Gene Regulatory Networks in Plant DevelopmentFrontiers Media SA20181 online resource (252 p.)Frontiers Research Topics2-88945-407-X During their life cycle plants undergo a wide variety of morphological and developmental changes. Impinging these developmental processes there is a layer of gene, protein and metabolic networks that are responsible for the initiation of the correct developmental transitions at the right time of the year to ensure plant life success. New omic technologies are allowing the acquisition of massive amount of data to develop holistic and integrative analysis to understand complex processes. Among them, Microarray, Next-generation Sequencing (NGS) and Proteomics are providing enormous amount of data from different plant species and developmental stages, thus allowing the analysis of gene networks globally. Besides, the comparison of molecular networks from different species is providing information on their evolutionary history, shedding light on the origin of many key genes/proteins. Moreover, developmental processes are not only genetically programed but are also affected by internal and external signals. Metabolism, light, hormone action, temperature, biotic and abiotic stresses, etc. have a deep effect on developmental programs. The interface and interplay between these internal and external circuits with developmental programs can be unraveled through the integration of systematic experimentation with the computational analysis of the generated omics data (Molecular Systems Biology). This Research Topic intends to deepen in the different plant developmental pathways and how the corresponding gene networks evolved from a Molecular Systems Biology perspective. Global approaches for photoperiod, circadian clock and hormone regulated processes; pattern formation, phase-transitions, organ development, etc. will provide new insights on how plant complexity was built during evolution. Understanding the interface and interplay between different regulatory networks will also provide fundamental information on plant biology and focus on those traits that may be important for next-generation agriculture.Botany & plant sciencesbicsscEvolutionGene Regulatory NetworksMolecular Systems BiologyOmicsPlant DevelopmentBotany & plant sciencesJose M. Romeroauth1318746Federico ValverdeauthAndrew GrooverauthBOOK9910346757003321Evolution of Gene Regulatory Networks in Plant Development3033512UNINA