Parties d'ouvrages collectifs (13)
  1. 8. Gauthier, M., Lambert, P., & Régnier, S. (2010). Microhandling and Micromanipulation Strategies. In Microrobotics for micromanipulation (1 ed., pp. 179-242). Wiley. doi:10.1002/9781118622810.ch3
  2. 9. Gauthier, M., Lambert, P., & Régnier, S. (2010). The Physics of the Microworld. In Microrobotics for micromanipulation (1 ed., pp. 1-98). Wiley. doi:10.1002/9781118622810.ch1
  3. 10. Agnus, J., Chaillet, N., Hafez, M., Gauthier, M., Lambert, P., & Régnier, S. (2008). La microrobotique: applications à la micromanipulation. In La physique du micromonde.
  4. 11. Régnier, S., Chaillet, N., & Lambert, P. (2008). La microrobotique: applications à la micromanipulation. In Micropréhension et stratégies de micromanipulation. Editions Hermès.
  5. 12. Lambert, P., Chaillet, N., & Hafez, M. (2008). La microrobotique: applications à la micromanipulation. In Actionneurs pour la microrobotique. Editions Hermès.
  6. 13. Chau, A., Lambert, P., Delchambre, A., & Bouillard, P. (2003). Behaviour of Flexure Hinges for Use as Articulations in High Precision Mechanisms. In H. Knobloch & Y. Kaminorz (Eds.), MicroNano Integration (pp. 287-288). Postdam: Springer.(VDI-Buch). doi:10.1007/978-3-642-18727-8_42
    7.   Articles dans des revues avec comité de lecture (105)
  7. 1. Rigaut, C., Giaprakis, A., Deruyver, L., Goole, J., Lambert, P., & Haut, B. (2024). The air conditioning in the nose of mammals depends on their mass and on their maximal running speed. Scientific Reports, 14(1). doi:10.1038/s41598-024-59768-z
  8. 2. Rigaut, C., Deruyver, L., Niesen, M., Vander Ghinst, M., Goole, J., Lambert, P., & Haut, B. (2023). What Are the Key Anatomical Features for the Success of Nose-to-Brain Delivery? A Study of Powder Deposition in 3D-Printed Nasal Casts. Pharmaceutics, 15(12), 2661. doi:10.3390/pharmaceutics15122661
  9. 3. Amez-Droz, L., Tunon De Lara Ramos, M., Collette, C., Caucheteur, C., & Lambert, P. (2023). Instrumented Flexible Glass Structure: A Bragg Grating Inscribed with Femtosecond Laser Used as a Bending Sensor. Sensors, 23(19), 11. doi:10.3390/s23198018
  10. 4. Tunon De Lara Ramos, M., Amez-Droz, L., Chah, K., Lambert, P., Collette, C., & Caucheteur, C. (2023). Femtosecond pulse laser-engineered glass flexible structures instrumented with an in-built Bragg grating sensor. Optics express, 31(18), 29730-29743. doi:10.1364/OE.497482
  11. 5. Piñan Basualdo, F., Bolopion, A., Gauthier, M., Lambert, P., & Piñan Basualdo, F. (2023). Solving the non-linear motion in a micromanipulation system powered by thermocapillary flows. IEEE Robotics and Automation Letters, 1-6. doi:10.1109/LRA.2023.3288378
  12. 6. Piñan Basualdo, F., Stéphan, O., Bolopion, A., Gauthier, M., & Lambert, P. (2023). Pose Control of Millimeter-Scale Objects in a Laser-Powered Thermocapillary Manipulation Platform. IEEE/ASME transactions on mechatronics, 1-10. doi:10.1109/TMECH.2023.3274371
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