Maik Rahlves
Maik Rahlves
Institute for Biomedical Optics - Universität zu Lübeck
Bestätigte E-Mail-Adresse bei
Zitiert von
Zitiert von
Fibre optic sensors for the structural health monitoring of building structures
K Bremer, M Wollweber, F Weigand, M Rahlves, M Kuhne, R Helbig, ...
Procedia Technology 26, 524-529, 2016
Flexible, fast, and low-cost production process for polymer based diffractive optics
M Rahlves, M Rezem, K Boroz, S Schlangen, E Reithmeier, B Roth
Optics express 23 (3), 3614-3622, 2015
Low-cost fabrication of all-polymer components for integrated photonics
M Rezem, A Günther, B Roth, E Reithmeier, M Rahlves
Journal of Lightwave Technology 35 (2), 299-308, 2017
Comparative study of presurgical skin infiltration depth measurements of melanocytic lesions with OCT and high frequency ultrasound
A Varkentin, M Mazurenka, E Blumenröther, M Meinhardt‐Wollweber, ...
Journal of biophotonics 10 (6-7), 854-861, 2017
Trimodal system for in vivo skin cancer screening with combined optical coherence tomography‐Raman and colocalized optoacoustic measurements
A Varkentin, M Mazurenka, E Blumenröther, L Behrendt, S Emmert, ...
Journal of biophotonics 11 (6), e201700288, 2018
Systematic errors on curved microstructures caused by aberrations in confocal surface metrology
M Rahlves, B Roth, E Reithmeier
Optics express 23 (8), 9640-9648, 2015
Cladded self-written multimode step-index waveguides using a one-polymer approach
A Günther, AB Petermann, U Gleissner, T Hanemann, E Reithmeier, ...
Optics letters 40 (8), 1830-1833, 2015
Hot embossing of polymer optical waveguides for sensing applications
M Rezem, A Günther, M Rahlves, B Roth, E Reithmeier
Procedia Technology 15, 514-520, 2014
Optisches Messen technischer Oberflächen: Messprinzipien und Begriffe
M Rahlves
Beuth Verlag, 2009
Refractive-index measurement and inverse correction using optical coherence tomography
J Stritzel, M Rahlves, B Roth
Optics letters 40 (23), 5558-5561, 2015
Confocal signal evaluation algorithms for surface metrology: uncertainty and numerical efficiency
M Rahlves, B Roth, E Reithmeier
Applied Optics 56 (21), 5920-5926, 2017
Realization and performance of an all-polymer optical planar deformation sensor
C Kelb, M Rahlves, E Reithmeier, B Roth
IEEE Sensors Journal 15 (12), 7029-7035, 2015
Automated misalignment compensating interconnects based on self-written waveguides
A Günther, S Schneider, M Rezem, Y Wang, U Gleissner, T Hanemann, ...
Journal of Lightwave Technology 35 (13), 2678-2684, 2017
Characterization of femtosecond laser written gratings in PMMA using a phase-retrieval approach
C Kelb, WM Pätzold, U Morgner, M Rahlves, E Reithmeier, B Roth
Optical Materials Express 6 (10), 3202-3209, 2016
Polymer-based transmission path for communication and sensing applications
M Rahlves, A Günther, M Rezem, B Roth
Journal of Lightwave Technology 37 (3), 729-735, 2018
Digital mirror devices and liquid crystal displays in maskless lithography for fabrication of polymer-based holographic structures
M Rahlves, C Kelb, M Rezem, S Schlangen, K Boroz, D Gödeke, M Ihme, ...
Journal of Micro/Nanolithography, MEMS, and MOEMS 14 (4), 041302-041302, 2015
Simple model to simulate oct-depth signal in weakly and strongly scattering homogeneous media
A Varkentin, M Otte, M Meinhardt-Wollweber, M Rahlves, M Mazurenka, ...
Journal of Optics 18 (12), 125302, 2016
Optically and rheologically tailored polymers for applications in integrated optics
U Gleißner, B Khatri, C Megnin, S Sherman, Y Xiao, M Hofmann, ...
Sensors and Actuators A: Physical 241, 224-230, 2016
Fabrication and sensing applications of multilayer polymer optical waveguides
M Rezem, A Günther, M Rahlves, B Roth, E Reithmeier
Procedia Technology 26, 517-523, 2016
Autofocusing system for spatial light modulator-based maskless lithography
S Schlangen, M Ihme, M Rahlves, B Roth
Applied optics 55 (8), 1863-1870, 2016
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