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The following pages do not link to other pages in Control Systems Technology Group.

Showing below up to 100 results in range #101 to #200.

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  1. Appendix PRE2020 1 Group2
  2. Archive hyperlink needed
  3. Arduino code 1
  4. Arduino code 2
  5. Articles bart
  6. Articles lighting
  7. Asada M. K. F. MacDorman, H. Ishiguro, Y. Kuniyoshi. (2017). Cognitive developmental robotics as a new paradigm for the design of humanoid robots.
  8. Auto-Selection Of Package Delivery Location Based On Estimated Time Of Delivery
  9. AutoRef Honors2019 minutes
  10. AutoRef Honors2019 team
  11. AutoRef MSD 1819
  12. AutoRef MSD 2019-2020
  13. AutoRef manuals
  14. Autonomous Aerial Cargo/Utility system
  15. Autonomous Drones for Assisting Rescue Services within the context of Natural Disasters
  16. Autonomous Measurement Drone for Remote Dangerous Source Location Mapping
  17. Autonomous Refueling Stations
  18. Autonomous and automatic landing system for drones
  19. Autonoom vliegen links
  20. BEP Shaft Rescue Robot (2022/2023, Q3)
  21. Background ARS
  22. Bar-Cohen, Y., & Breazeal, C., (2003). Biologically inspired intelligent robots.
  23. Bartneck, C. et al. (2009). My Robotic Doppelgänger - A Critical Look at the Uncanny Valley
  24. Beamer with Sidebar
  25. Beantwoorde deelvragen
  26. Beantwoorden vraag waarom het een probleem is dat blinden en slechtzienden minder werken dan zienden.
  27. Beschrijving van 3 banen waar robotica eventueel zouden kunnen helpen
  28. Botsingdetectie
  29. Breazeal, C. & Scassellatie, B. (2002). Robots That Imitate Humans.
  30. Brenna D. Argall, Sonia Chernova, Manuela Veloso, Brett Browning (2008), A survey of robot learning from demonstration, Robotics and Autonomous Systems
  31. Broad SotA
  32. C. G. Atkeson, J. G. Hale, F. Pollick, M. Riley, S. Kotosaka, S. Schaal, T. Shibata, G. Tevatia, A. Ude, S. Vijayakumar, E. Kawato, M. Kawato. (2000). Using Humanoid Robots To Study Human Behavior.
  33. CAT
  34. Calculation of Optimal Magnetic Force for Automatic Control Magnetic Force of the Window Cleaning Robot
  35. Can drones deliver?
  36. Can unmanned aerial systems (drones) be used for the routine transport of chemistry, hematology, and coagulation laboratory specimens?
  37. Chin Chang Ho, Karl F. MacDorman (2016), Measuring the Uncanny Valley Effect
  38. Chronological Document
  39. Chung-En Yu (2020). Humanlike robots as employees in the hotel industry: Thematic content analysis of online reviews.
  40. Civilian drones, privacy, and the federal-state balance
  41. Clairvoyance
  42. Cleaning
  43. Climbing cleaning robot for vertical surfaces
  44. Coaching Questions
  45. Coaching Questions Group 1
  46. Coaching Questions Group 11
  47. Coaching Questions Group 12
  48. Coaching Questions Group 13
  49. Coaching Questions Group 14
  50. Coaching Questions Group 15
  51. Coaching Questions Group 16
  52. Coaching Questions Group 17
  53. Coaching Questions Group 18
  54. Coaching Questions Group 2
  55. Coaching Questions Group 3
  56. Coaching Questions Group 4
  57. Coaching Questions Group 5
  58. Coaching Questions Group 7
  59. Coaching Questions Group 8
  60. Code group5 2020
  61. Collected interviews
  62. Comparison motion planning algorithms
  63. Conclusie PRE2Groep2
  64. Control for Dummies
  65. Cost function 2016 a2
  66. DMC: Tips and Tricks
  67. Daniël Pijnenborg
  68. Decision tree - Group 4 - 2018/2019, Semester B, Quartile 3
  69. Deelvragen
  70. Deliverables and milestones of group 12
  71. Delivery platform for unmanned areal vehicles
  72. Dense topological maps and partial pose estimation for visual control of an autonomous cleaning robot
  73. Design and Control of an Unmanned Aerial Vehicle for Autonomous Parcel Delivery with Transition from Vertical Take-off to Forward Flight
  74. Design and Kinematic Analysis of Tethered Guiding Vehicle (TGV) for façade window cleaning
  75. Design and stability analysis of a novel wall-climbing robotic platform (ROPE RIDE)
  76. Design of a small-scale autonomous amphibious vehicle
  77. Detection Skill
  78. Development of a High Efficiency and High Reliable Glass Cleaning Robot with a Dirt Detect Sensor
  79. Dieter Vanderelst, Alan Winfield (2017), Rational imitation for robots: the cost difference model
  80. Documents Ruud
  81. Documents Ruud van den Bogaert
  82. Doering, M., & Glas, D., & Ishiguro, H., (2019). Modeling Interaction Structure for Robot Imitation Learning of Human Social Behavior.
  83. Done
  84. Drive trough a corridor
  85. Drone-Aided Healthcare Services for Patients with Chronic diseases in Rural Areas
  86. Drone Operated Delivery Receptacle
  87. Drone Referee - MSD 2017/18
  88. Drone Referee - MSD 2018/9
  89. Drone delivery models for healthcare
  90. Drone shipping versus truck delivery in a cross-docking system with multiple fleets and products
  91. Drone transport of microbes in blood and sputum laboratory specimens
  92. Drone transportation of blood products
  93. Drones in Logistics: A Feasible Future or a waste of effort
  94. E-box/Install manual
  95. E-box/Install manual/FAQ
  96. E-box/Students Manual
  97. E-box/User manual
  98. EDrive
  99. EUTAFT Log
  100. EUTAFT Software

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