DOI INFORMATION FOR 10.4173:


General information about the DOI system can be found here and here. A DOI name is a digital object identifier for any object of intellectual property. A DOI name provides a means of persistently identifying a piece of intellectual property on a digital network and associating it with related current data in a structured extensible way. DOI was accepted as an ISO standard in 2010.
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If you have ever tried to follow an URL in an article older than 5-10 years, more often than not you will find that the URL is no longer active. The DOI system is an attempt to overcome this deficiency by providing stable and permanent references for intellectual property on the web.

The MIC journal has implemented the DOI system for every single article published in MIC since the foundation year in 1980. The DOI prefix for MIC is 10.4173 and an individual article has been assigned a DOI on the following format: 10.4173/mic.year.no.paperno. For example, the first article published in MIC by Oddvar Hallingstad has the following DOI: 10.4173/mic.1980.1.1 and the following permanent URL http://dx.doi.org/10.4173/mic.1980.1.1. This permanent URL links back to the www.mic-journal.no website. If the MIC website is moved in the future, the DOI information will be updated to point to the new address.

Another advantage of the DOI system, is the possibility to register all the references in an article in a structured manner. All the references made in MIC articles starting from 1980 have been submitted into the DOI system. The effect is an increased visibility of MIC articles, which again will lead to a wider audience. MIC also participates in the 'cited-by' system, which can be seen for this article. 'cited-by' shows which other papers have included the actual paper in the reference lists.

The MIC class files for pdfLaTeX found in the Author Information have commands for embedding DOI information in the PDF files. Prospective authors for future MIC articles will receive the DOI identification when the article is accepted. Authors are encouraged to embed the tag into the PDF file themselves using pdflatex prior to publication. Authors are also encouraged to embed DOI tags in their reference lists.

Click on the links below to see the external DOI forward links to MIC:
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DOI Forward Links to MIC for Year: 2020

 Total number of MIC articles in 2020  19
 Total number of DOI citations  51
 Average citations per article   2.68 

2020, Vol. 41, No. 4:
1.Peter Fritzson, Adrian Pop, Karim Abdelhak, Adeel Ashgar, Bernhard Bachmann, Willi Braun, Daniel Bouskela, Robert Braun, Lena Buffoni, Francesco Casella, Rodrigo Castro, Rüdiger Franke, Dag Fritzson, Mahder Gebremedhin, Andreas Heuermann, Bernt Lie, Alachew Mengist, Lars Mikelsons, Kannan Moudgalya, Lennart Ochel, Arunkumar Palanisamy, Vitalij Ruge, Wladimir Schamai, Martin Sjölund, Bernhard Thiele, John Tinnerholm and Per Östlund, “The OpenModelica Integrated Environment for Modeling, Simulation, and Model-Based Development”, pp. 241-295
DOI forward links to this article:
[1] Alachew Mengist, Lena Buffoni and Adrian Pop (2021), doi:10.3390/electronics10080983
[2] A. Masoom, A. Guironnet, A.A. Zeghaida, T. Ould-Bachir and J. Mahseredjian (2021), doi:10.1016/j.epsr.2021.107340
[3] Gernot Steindl and Wolfgang Kastner (2021), doi:10.3390/app11125633
[4] Michael Wetter, Paul Ehrlich, Antoine Gautier, Milica Grahovac, Philip Haves, Jianjun Hu, Anand Prakash, David Robin and Kun Zhang (2021), doi:10.1016/j.energy.2021.121501
[5] Nikola Makedonski and Georgi Milev (2021), doi:10.1109/ELMA52514.2021.9502971
[6] A. Guironnet, F. Rosiere, G. Bureau and M. Saugier (2021), doi:10.1109/SEST50973.2021.9543360
[7] Francisco M. Marquez, Pedro J. Zufiria and Luis J. Yebra (2021), doi:10.1109/ACCESS.2021.3115038
[8] Damir Sedlar and Luka Kreso (2021), doi:10.23919/SpliTech52315.2021.9566428
[9] Alexey M. Romanov, Vladimir D. Yashunskiy and Wei-Yu Chiu (2021), doi:10.1109/ACCESS.2021.3124951
[10] Sudhakar Kumar, Rahul Paknikar, Nikhil Sharma and Kannan M. Moudgalya (2021), doi:10.1109/ICCMA54375.2021.9646198
[11] Zhelun Chen, Jin Wen, Anthony J. Kearsley and Amanda Pertzborn (2022), doi:10.1080/19401493.2021.2007285
[12] Vyaas Gururajan and Riccardo Scarcelli (2022), doi:10.1088/1361-6463/ac4726
[13] Yiwei Wu, Yawei Mao, Liyou Xu and Feng Chen (2022), doi:10.1371/journal.pone.0263838
[14] Kathryn Hinkelman, Jing Wang, Wangda Zuo, Antoine Gautier, Michael Wetter, Chengliang Fan and Nicholas Long (2022), doi:10.1016/j.apenergy.2022.118654
[15] Peter Fritzson (2021), doi:10.1109/WSC52266.2021.9715443
[16] Yongqiang Guo (2022), doi:10.1007/s00521-022-07088-6
[17] Giuseppe Baselli, Gianfranco Fiore, Francesco Casella, Simone Cinquemani, Roberto Vigano, Antonio Pesenti and Alberto Zanella (2022), doi:10.1109/OJEMB.2022.3152673
[18] Camila Correa-Jullian and Katrina M. Groth (2022), doi:10.1016/j.ijhydene.2022.04.048
[19] Valentina Zambrano, Johannes Mueller-Roemer, Michael Sandberg, Prasad Talasila, Davide Zanin, Peter Gorm Larsen, Elke Loeschner, Wolfgang Thronicke, Dario Pietraroia, Giuseppe Landolfi, Alessandro Fon (2022), doi:10.1016/j.array.2022.100176
[20] John Tinnerholm, Adrian Pop and Martin Sjolund (2022), doi:10.3390/electronics11111772
[21] Carla Martin-Villalba and Alfonso Urquia (2022), doi:10.1109/ACCESS.2022.3179712
[22] Sandra Tellez-Gutierrez and Oscar Duarte-Velasco (2022), doi:10.22430/22565337.2357
[23] Alireza Masoom, Jean Mahseredjian, Tarek Ould-Bachir and Adrien Guironnet (2022), doi:10.1109/TPWRD.2021.3111127
[24] Matteo Luigi De Pascali, Simone Bosotti, Paolo Curatolo, Lavinia Marina Paola Ghilardi, Francesco Casella, Emanuele Martelli, Daniele Barbati and Roberto Palazzo (2022), doi:10.1016/j.ifacol.2022.07.055
[25] William Fornaciari, Federico Terraneo, Giovanni Agosta, Zummo Giuseppe, Luca Saraceno, Giorgia Lancione, Daniele Gregori and Massimo Celino (2022), doi:10.1007/978-3-031-15074-6_27
2.Lars Ivar Hatledal, Robert Skulstad, Guoyuan Li, Arne Styve and Houxiang Zhang, “Co-simulation as a Fundamental Technology for Twin Ships”, pp. 297-311
DOI forward links to this article:
[1] Guoyuan Li, Erlend Holseker, Arvin Khodabandeh, Isak Gamnes Sneltvedt, Erik BjornoY and Houxiang Zhang (2021), doi:10.1109/ICMA52036.2021.9512631
[2] Jan-Erik Giering and Alexander Dyck (2021), doi:10.1515/auto-2021-0082
[3] Icaro Aragao Fonseca, Henrique Murilo Gaspar, Pedro Cardozo de Mello and Humberto Akira Uehara Sasaki (2022), doi:10.1016/j.cad.2021.103191
[4] Han Li, Guoxin Wang, Jinzhi Lu and Dimitris Kiritsis (2022), doi:10.3233/ICA-220677
[5] Rasmus E. Nielsen, Dimitrios Papageorgiou, Lazaros Nalpantidis, Bugge T. Jensen and Mogens Blanke (2022), doi:10.1016/j.oceaneng.2022.111579
3.Petter SolnørA Cryptographic Toolbox for Feedback Control Systems”, pp. 313-332
DOI forward links to this article:
[1] Oystein Volden, Petter Solnor, Slobodan Petrovic and Thor I. Fossen (2021), doi:10.1007/s10846-021-01472-5
[2] Petter Solnor, Oystein Volden, Kristoffer Gryte, Slobodan Petrovic and Thor I. Fossen (2022), doi:10.1002/rob.22068
2020, Vol. 41, No. 3:
1.Mohamed Yousri, Georg Jacobs and Stephan Neumann, “Impact of fiber versus steel ropes on the lifetime of crane winches”, pp. 129-139
2.Dipendra Subedi, Ilya Tyapin and Geir Hovland, “Review on Modeling and Control of Flexible Link Manipulators”, pp. 141-163
DOI forward links to this article:
[1] Hasan Huseyin Bilgic, Muhammed Arif Sen, Ahmet Yapici, Hakan Yavuz and Mete Kalyoncu (2021), doi:10.1007/s13369-021-05428-7
[2] Dipendra Subedi, Ilya Tyapin and Geir Hovland (2021), doi:10.3390/robotics10020070
[3] Ahmed A. Shabana and Zhengfeng Bai (2022), doi:10.1115/1.4051438
[4] Dipendra Subedi, Teodor Nilsen Aune, Ilya Tyapin and Geir Hovland (2022), doi:10.1109/ACCESS.2022.3144404
[5] Ruihai Geng, Yushu Bian, Liang Zhang and Yizhu Guo (2022), doi:10.3390/machines10040284
[6] Junjie Gong, Ganwei Cai, Wei Wei, Kechen Zhang and Sixu Peng (2022), doi:10.1109/ACCESS.2022.3165053
[7] Fernanda Thais Colombo and Maira Martins da Silva (2022), doi:10.1016/j.conengprac.2022.105306
3.Njål Tengesdal and Christian Holden, “Identification and Optimal Control for Surge and Swab Pressure Reduction While Performing Offshore Drilling Operations”, pp. 165-184
4.Søren Ketelsen, Torben Ole Andersen, Morten K. Ebbesen and Lasse Schmidt, “A Self-Contained Cylinder Drive with Indirectly Controlled Hydraulic Lock”, pp. 185-205
DOI forward links to this article:
[1] Soren Ketelsen, Sebastian Michel, Torben O. Andersen, Morten Kjeld Ebbesen, Jurgen Weber and Lasse Schmidt (2021), doi:10.3390/en14092375
[2] Konrad Johan Jensen, Morten Kjeld Ebbesen and Michael Rygaard Hansen (2021), doi:10.3390/en14206566
[3] Lasse Schmidt and Kenneth Vorbol Hansen (2022), doi:10.3390/en15031228
[4] Jiaming Zhang, Lingwei Li, Xinglong Zhang, Tianhong Zhang and Yuan Yuan (2022), doi:10.3390/app12063089
5.Aksel Sveier, Torstein A. Myhre and Olav Egeland, “Extrinsic calibration for motion estimation using unit quaternions and particle filtering”, pp. 207-221
6.Viktor Hristov Donkov, Torben Ole Andersen and Morten K. Ebbesen, “An analysis of Model Predictive Control with Integral Action applied to Digital Displacement Cylinders”, pp. 223-239
2020, Vol. 41, No. 2:
1.Åse Neverlien, Signe Moe and Jan T. Gravdahl, “Compressor Surge Control Using Lyapunov Neural Networks”, pp. 41-49
DOI forward links to this article:
[1] Jianhua Sun, Hai Gu, Jie Zhang and Hashem Imani Marrani (2021), doi:10.1177/09596518211057423
2.Jannik Hartwig Jakobsen and Michael R. Hansen, “Steady State Counterbalance Valve Modeling with the Influence of Synthetic Ester Oils Using CFD”, pp. 51-64
3.Ludmila Vesjolaja, Bjørn Glemmestad and Bernt Lie, “Dynamic model for simulating transient behaviour of rotary drum granulation loop”, pp. 65-77
DOI forward links to this article:
[1] Ludmila Vesjolaja, Bjorn Glemmestad and Bernt Lie (2020), doi:10.3390/pr8111423
[2] Amit V. Patil, Jesse Hofsteenge, Jakub M. Bujalski and Stein T. Johansen (2021), doi:10.1007/s40571-021-00438-6
4.Asanthi Jinasena and Roshan Sharma, “Adaptive Moving Horizon Estimator for Return Flow Rate Estimation using Fluid Levels of a Venturi Channel”, pp. 79-90
5.Erik KyrkjebøA Guide to Student-active Online Learning in Engineering”, pp. 91-107
DOI forward links to this article:
[1] Damjan Fujs, Simon Vrhovec, Bo tjan vanut and Damjan Vavpoti (2022), doi:10.1016/j.compedu.2022.104448
[2] Hanneke Theelen and Dave H. J. van Breukelen (2022), doi:10.1111/jcal.12705
6.Geir-Arne Moslått and Michael R. Hansen, “Practice for determining friction in hydraulic winch systems”, pp. 109-120
7.Shadi Attar and Finn Haugen, “Model-based optimal recovery of methane production in an anaerobic digestion reactor”, pp. 121-128
DOI forward links to this article:
[1] Victor Alcaraz-Gonzalez, Fabian Azael Fregoso-Sanchez, Victor Alvarez-Gonzalez and Jean-Philippe Steyer (2021), doi:10.3390/pr9071153
[2] Victor Alcaraz-Gonzalez (2022), doi:10.1007/978-3-030-95288-4_12
2020, Vol. 41, No. 1:
1.Erik Andreas Løken, Jens Løkkevik and Dan Sui, “Automated drilling algorithms implementation on a laboratory drilling rig”, pp. 1-11
2.Rune Husveg, Trygve Husveg, Niels van Teeffelen, Morten Ottestad and Michael R. Hansen, “Variable Step Size P&O Algorithms for Coalescing Pump/Deoiling Hydrocyclone Produced Water Treatment System”, pp. 13-27
DOI forward links to this article:
[1] Hana D. Dawoud, Haleema Saleem, Nasser Abdullah Alnuaimi and Syed Javaid Zaidi (2021), doi:10.3390/w13243573
3.Remzija Cerimagic, Lisbeth Fajstrup, Torben Ole Andersen and Per Johansen, “An Isogeometric Analysis Approach to Kinematics of Spatial Rigid Multibody Systems with Imperfect Joints”, pp. 29-40