Dieses Bild zeigt Andrea Toulouse

Andrea Toulouse

Frau Dr.

Gruppenleiterin 3D-gedruckte Mikrooptik und Simulation
Institut für Technische Optik
3D-gedruckte Mikrooptik und Simulation

Kontakt

+49 711 685 66648
 +49 711 685 66586

Pfaffenwaldring 9
D - 70569 Stuttgart
Deutschland
Raum: 1.228

Fachgebiet

  • Koordination Mikro-3D-Druck
 

  1. 2025

    1. K. Doth, M. Wende, J. Drozella, T. Haist, A. Herkommer, and A. Toulouse, “Miniaturized holographic twin trap 3D-printed via two-photon lithography,” Journal of Optical Microsystems, vol. 5, Art. no. 2, 2025, doi: 10.1117/1.JOM.5.2.024501.
    2. R. Chen et al., “Low background fluorescence 3D-printed micro-lens for imaging of vulnerable atherosclerotic plaques,” APL Photonics, vol. 10, Art. no. 4, Apr. 2025, doi: 10.1063/5.0247546.
    3. F. Rothermel et al., “Magnetically actuatable 3D-printed endoscopic microsystems,” Communications Engineering, vol. 4, Art. no. 1, Apr. 2025, doi: 10.1038/s44172-025-00403-8.
    4. M. Wende, K. Doth, M. Heymann, and A. Toulouse, “3D-printed immersion micro optics,” Light: Advanced Manufacturing, vol. 6, Art. no. 19, Mar. 2025, doi: 10.37188/lam.2025.019.

  2. 2024

    1. Ö. Atmaca et al., “Elastographic Measurements Using Fourier Transform Profilometry for Tissue Differentiation in Oncology,” in DGaO Proceedings 2024, Aug. 2024, p. P20. [Online]. Available: https://www.dgao-proceedings.de/download/125/125_p20.pdf
    2. A. Toulouse, S. Thiele, V. Aslani, and A. Herkommer, “Verfahren zum Schutz von Objektiven für neue Fotolacke in der hochauflösenden Zweiphotonenlithografie,” in DGaO Proceedings 2024, DGaO, Ed., 2024. [Online]. Available: https://www.dgao-proceedings.de/abstract/abstract_only.php?id=3069
    3. V. Aslani, A. Toulouse, M. Schmid, H. Giessen, T. Haist, and A. Herkommer, “3D-Druck von farbigen Mikrooptiken,” D. Proceedings, Ed., 2024.
    4. C. Jimenez, A. Toulouse, and A. Herkommer, “Beam shaping elements for single photon sources based on 3D printed micro-optics,” in EPJ Web of Conferences, L. De Stefano, R. Velotta, and E. Descrovi, Eds., EDP Sciences, 2024, p. 3007. doi: 10.1051/epjconf/202430903007.
    5. M. Wende, J. Drozella, A. Toulouse, and A. M. Herkommer, “Fast vector wave optical simulation methods for application on 3D-printed microoptics,” Journal of Optical Microsystems, vol. 4, Art. no. 2, 2024, doi: 10.1117/1.JOM.4.2.024501.
    6. A. Toulouse, F. Rothermel, J. Drozella, S. Thiele, and A. Herkommer, “A 3D-printed fiber core multiplexing endoscope,” in 3D Printed Optics and Additive Photonic Manufacturing IV, G. von Freymann, A. M. Herkommer, and M. Flury, Eds., SPIE, Jun. 2024, p. 8. doi: 10.1117/12.3016279.
    7. R. Chen, F. Rothermel, A. Toulouse, P. Flad, H. Giessen, and A. Herkommer, “Miniaturised 3D printed fibre-optic probe for autofluorescence detection of human plaques,” in Proceedings Volume PC12820, Endoscopic Microscopy XIX, S. Proc., Ed., 2024, p. PC128200A. doi: https://doi.org/10.1117/12.3002467.

  3. 2023

    1. J. Li et al., “3D micro-printing of miniaturized fiber-optic probes capable of multi-modal imaging and beam tailoring,” in Optical Coherence Tomography and Coherence Domain Optical Methods in Biomedicine XXVII, J. A. Izatt and J. G. Fujimoto, Eds., SPIE, 2023, p. PC1236703. doi: 10.1117/12.2652181.
    2. V. Aslani, A. Toulouse, M. Schmid, H. Giessen, T. Haist, and A. Herkommer, “3D printing of colored micro-optics,” Optical Materials Express, vol. 13, Art. no. 5, Apr. 2023, doi: 10.1364/ome.489681.

  4. 2022

    1. A. Toulouse et al., “Ultra-compact 3D-printed wide-angle cameras realized by multi-aperture freeform optical design,” Opt. Express, vol. 30, Art. no. 2, Jan. 2022, doi: 10.1364/OE.439963.
    2. A. Toulouse et al., “High resolution femtosecond direct laser writing with wrapped lens,” Opt. Mater. Express, vol. 12, Art. no. 9, Sep. 2022, doi: 10.1364/OME.468534.
    3. J. Drozella et al., “Micro-3D-printed multi-aperture freeform ultra-wide-angle systems: production, characterization, and correction,” in Laser-based Micro- and Nanoprocessing XVI, A. Watanabe and R. Kling, Eds., SPIE, 2022, p. 119890V. doi: 10.1117/12.2609844.
    4. M. D. Schmid, A. Toulouse, S. Thiele, S. Mangold, A. M. Herkommer, and H. Giessen, “3D Direct Laser Writing of Highly Absorptive Photoresist for Miniature Optical Apertures,” Advanced Functional Materials, p. 2211159, Dec. 2022, doi: 10.1002/adfm.202211159.
    5. A. Toulouse, J. Drozella, S. Thiele, H. Giessen, and A. M. Herkommer, “Complex 3D printed microoptical systems: from a pinhole camera to a spectrometer,” in 3D Printed Optics and Additive Photonic Manufacturing III, A. M. Herkommer, G. von Freymann, and M. Flury, Eds., SPIE, 2022, p. PC1213504. doi: 10.1117/12.2624165.
    6. M. Wende, J. Drozella, A. Toulouse, and A. M. Herkommer, “Fast algorithm for the simulation of 3D-printed microoptics based on the vector wave propagation method,” Optics Express, vol. 30, Art. no. 22, Oct. 2022, doi: 10.1364/oe.469178.

  5. 2021

    1. S. Ristok, S. Thiele, A. Toulouse, A. M. Herkommer, and H. Giessen, “Stitching-free 3D printing of millimeter-sized highly transparent spherical and aspherical optical components,” in Conference on Lasers and Electro-Optics, Optica Publishing Group, 2021, p. ATh1R. doi: 10.1364/CLEO_AT.2021.ATh1R.1.
    2. A. Toulouse, J. Drozella, S. Thiele, H. Giessen, and A. Herkommer, “3D-printed miniature spectrometer for the visible range with a 100 × 100 μm<sup>2</sup> footprint,” Light: Advanced Manufacturing, vol. 2, Art. no. 1, 2021, doi: 10.37188/lam.2021.002.

  6. 2020

    1. S. Ristok, S. Thiele, A. Toulouse, A. M. Herkommer, and H. Giessen, “Stitching-free 3D printing of millimeter-sized highly transparent spherical and aspherical optical components,” Opt. Mater. Express, vol. 10, Art. no. 10, Oct. 2020, doi: 10.1364/OME.401724.
    2. S. Schmidt et al., “Tailored micro-optical freeform holograms for integrated complex beam shaping,” Optica, vol. 7, Art. no. 10, Oct. 2020, doi: 10.1364/OPTICA.395177.
    3. S. Thiele, A. Toulouse, S. Ristok, H. Giessen, and A. Herkommer, “Translating optical design freedom into 3D printed complex micro-optics (Conference Presentation),” in 3D Printed Optics and Additive Photonic Manufacturing II, A. M. Herkommer, G. von Freymann, and M. Flury, Eds., SPIE, 2020, p. 1134904. doi: 10.1117/12.2559198.

  7. 2019

    1. A. Toulouse, S. Thiele, and A. Herkommer, “Virtual reality headset using a gaze-synchronized display system,” in Optical Design Challenge 2019, B. C. Kress, Ed., SPIE, 2019, p. 1104009. doi: 10.1117/12.2523920.
    2. J. Drozella, A. Toulouse, S. Thiele, and A. M. Herkommer, “Fast and comfortable GPU-accelerated wave-optical simulation for imaging properties and design of highly aspheric 3D-printed freeform microlens systems,” in Novel Optical Systems, Methods, and Applications XXII, C. F. Hahlweg and J. R. Mulley, Eds., SPIE, 2019, p. 1110506. doi: 10.1117/12.2528843.

  8. 2018

    1. A. Toulouse, S. Thiele, H. Giessen, and A. M. Herkommer, “Alignment-free integration of apertures and nontransparent hulls into 3D-printed micro-optics,” Opt. Lett., vol. 43, Art. no. 21, Nov. 2018, doi: 10.1364/OL.43.005283.
    2. A. Hartung, S. Thiele, J. Drozella, H. Giessen, and A. Herkommer, “Schwärzen von 3D-gedruckten Mikrooptiken mittels Inkjet-Verfahren,” DGaO Proceedings, 2018.
Das ITO-Team im Jahr 2024

ITO-Team 2024

fehlend: Andrea Rüdinger, Christian Schober, Carlos Eduardo Jimenez, Kevin Treptow, Giancarlo Pedrini, Heiko Bieger, Karsten Frenner, Thomas Schoder

ITO-Team 2023

fehlend: Alexander Gröger, Anton Savchenko, Carlos Eduardo Jimenez, Christina Vogelmann, Giancarlo Pedrini, Hülya Samhat, Joshua Trapp, Karsten Frenner, Thomas Schoder

ITO-Team 2022

Das ITO-Team im Jahr 2021

ITO-Team 2021

Das ITO-Team im Jahr 2019

ITO-Team 2019

Das ITO-Team im Jahr 2016

ITO-Team 2017

Das ITO-Team im Jahr 2015

ITO-Team 2015

Das ITO-Team im Jahr 2013

ITO-Team 2013

Das ITO-Team im Jahr 2011

ITO-Team 2011

Das ITO-Team im Jahr 2009

ITO-Team 2009

Das ITO-Team im Jahr 2008

ITO-Team 2008

Das ITO-Team im Jahr 2007

ITO-Team 2007

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