<?xml version="1.0"?><rdf:RDF xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:edm="http://www.europeana.eu/schemas/edm/" xmlns:wgs84_pos="http://www.w3.org/2003/01/geo/wgs84_pos" xmlns:foaf="http://xmlns.com/foaf/0.1/" xmlns:rdaGr2="http://rdvocab.info/ElementsGr2" xmlns:oai="http://www.openarchives.org/OAI/2.0/" xmlns:owl="http://www.w3.org/2002/07/owl#" xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#" xmlns:ore="http://www.openarchives.org/ore/terms/" xmlns:skos="http://www.w3.org/2004/02/skos/core#" xmlns:dcterms="http://purl.org/dc/terms/"><edm:WebResource rdf:about="http://www.dlib.si/stream/URN:NBN:SI:DOC-LN81VB1W/bccbf900-3d78-4abe-87bd-4b496e427b85/PDF"><dcterms:extent>1429 KB</dcterms:extent></edm:WebResource><edm:WebResource rdf:about="http://www.dlib.si/stream/URN:NBN:SI:DOC-LN81VB1W/b810c694-3264-4b90-90dc-79e2c494776d/TEXT"><dcterms:extent>0 KB</dcterms:extent></edm:WebResource><edm:ProvidedCHO rdf:about="URN:NBN:SI:DOC-LN81VB1W"><dcterms:issued>2025</dcterms:issued><dc:creator>Jiao, Z. H.</dc:creator><dc:format xml:lang="sl">številka:2</dc:format><dc:format xml:lang="sl">letnik:20</dc:format><dc:format xml:lang="sl">str. 173-190</dc:format><dc:identifier>DOI:10.14743/apem2025.2.534</dc:identifier><dc:identifier>ISSN:1854-6250</dc:identifier><dc:identifier>COBISSID_HOST:265643523</dc:identifier><dc:identifier>URN:URN:NBN:SI:doc-LN81VB1W</dc:identifier><dc:language>en</dc:language><dc:publisher xml:lang="sl">Fakulteta za strojništvo, Inštitut za proizvodno strojništvo</dc:publisher><dc:source xml:lang="sl">Advances in production engineering and management</dc:source><dc:subject xml:lang="en">low-carbon multimodal transport</dc:subject><dc:subject xml:lang="sl">multimodalni transport</dc:subject><dc:subject xml:lang="sl">nizkoogljični transport</dc:subject><dc:subject xml:lang="sl">optimizacija poti</dc:subject><dc:subject xml:lang="sl">optimizacija z rojem delcev</dc:subject><dc:subject xml:lang="en">particle swarm optimization</dc:subject><dc:subject xml:lang="en">route optimization</dc:subject><dc:subject xml:lang="en">timetable limit</dc:subject><dc:subject xml:lang="sl">tovorna logistika</dc:subject><dc:subject xml:lang="en">vehicle logistics</dc:subject><dc:title xml:lang="sl">Low-carbon multimodal vehicle logistics route optimization with timetable limit using Particle Swarm Optimization|</dc:title><dc:description xml:lang="sl">Optimizing the multimodal transport route for vehicles is crucial for reducing costs, enhancing efficiency, and minimizing emissions in the vehicle logistics industry. This study addresses several operational challenges, including seasonal fluctuations in vehicle sales, the scheduling of transportation modes, and client-specific order timing requirements. This paper presents a 0-1 integer programming model under carbon trading policy considering the timetable limit, with the objective of minimizing the aggregate costs of transportation, transshipment, short-term storage, time-window penalties, and carbon emissions. A linear weight reduction technique is employed to formulate the Improved Particle Swarm Optimization (IPSO) algorithm with dynamic inertia weights for model resolution. The model and algorithm's efficacy are validated by a real-world case study of multi-modal transport in China. The results reveal that the IPSO algorithm reduced convergence times by 30.38 % and 17.78 % in off-season and peak season data, respectively, compared to the traditional PSO algorithm. Additionally, the optimized multimodal transport solution reduced unit costs by 19.3 % and 14.8 %, respectively. The findings indicate that transport time-liness significantly influences optimal route selection. Factors such as extended short-term storage duration, missed shipping schedules, and expedited orders compel multimodal transport to shift toward road transport. An increase in carbon trading prices effectively encourages a shift from road transport to multimodal transport; however, excessively high carbon trading prices fail to regulate this transition. Furthermore, as transport distance increases, the transport costs and carbon emission advantages associated with multimodal transport also increase correspondingly. This research advances multimodal logistics by integrating seasonal variations and carbon trading into a novel optimization framework</dc:description><edm:type>TEXT</edm:type><dc:type xml:lang="sl">znanstveno časopisje</dc:type><dc:type xml:lang="en">journals</dc:type><dc:type rdf:resource="http://www.wikidata.org/entity/Q361785" /></edm:ProvidedCHO><ore:Aggregation rdf:about="http://www.dlib.si/?URN=URN:NBN:SI:DOC-LN81VB1W"><edm:aggregatedCHO rdf:resource="URN:NBN:SI:DOC-LN81VB1W" /><edm:isShownBy rdf:resource="http://www.dlib.si/stream/URN:NBN:SI:DOC-LN81VB1W/bccbf900-3d78-4abe-87bd-4b496e427b85/PDF" /><edm:rights rdf:resource="http://creativecommons.org/licenses/by/4.0/" /><edm:provider>Slovenian National E-content Aggregator</edm:provider><edm:intermediateProvider xml:lang="en">National and University Library of Slovenia</edm:intermediateProvider><edm:dataProvider xml:lang="sl">Univerza v Mariboru, Fakulteta za strojništvo</edm:dataProvider><edm:object rdf:resource="http://www.dlib.si/streamdb/URN:NBN:SI:DOC-LN81VB1W/maxi/edm" /><edm:isShownAt rdf:resource="http://www.dlib.si/details/URN:NBN:SI:DOC-LN81VB1W" /></ore:Aggregation></rdf:RDF>