References
- Soper, TD, Haynor DR, Glenny RW, et al. In vivo validation of a hybrid tracking system for navigation of an ultrathin bronchoscope within peripheral airways. IEEE Trans Biomed Eng. 2010;57(3):736–745.
- Franz AM, Haidegger T, Birkfellner W, et al. Electromagnetic tracking in medicine—a review of technology, validation, and applications. IEEE Trans Med Imaging. 2014;33(8):1702–1725.
- Russo S, Dario P, Menciassi A. A novel robotic platform for laser-assisted transurethral surgery of the prostate. IEEE Trans Biomed Eng. 2015;62(2):489–500.
- Li M, Bien T, Rose G. FPGA based electromagnetic tracking system for fast catheter navigation. Int J Sci Eng Res. 2013;4(9):2566–2570.
- Peters T, Cleary K. Image-guided interventions: technology and application. Springer; 2008.
- Roy SH, Cole T, Don Gilmore L, et al. High-resolution tracking of motor disorders in Parkinson’s disease during unconstrained activity. Movement Disord. 2013:1–8.
- Badesa FJ, Morales R, Garcia-Aracil NM, et al. Dynamic adaptive system for robot-assisted motion rehabilitation. IEEE Sys J. 2016;10(3):984–991.
- Cattin E, Roccella S, Vitiello N, et al. Design and development of a novel robotic platform for neuro-robotics applications: the NEURobotics ARM (NEURARM). Adv Robotics. 2018;22(1):3–37
- Andria G, Attivissmo F, Giaquinto N, et al. Functional evaluation of handgrip signals for Parkinsonian patients. IEEE Trans Instrumentation Meas. 2006;55(5):1467–1472.
- Merlo A, Farina D, Merletti R. A fast and reliable technique for muscle activity detection from surface EMG signals. IEEE Trans Biomed Eng. 2003;50(3):316–323
- Zhoua H, Hu H. Human motion tracking for rehabilitation—a survey. Biomed Signal Process Control. 2008;3(1):1–18.
- Adamo F, Andria G, Attivissimo F, et al. A comparative study on mother wavelet selection in ultrasound image denoising. Measurement. 2013;46(8):2447–2456.
- Hendrik RE, Newman FD, Hendee WR. MR imaging technology: maximizing the signal-to-noise ratio from a single tissue. Radiology. 156(3):749–752.
- Frush DP, Slack CC, Hollingsworth CL, et al. Computer-simulated radiadose reduction for abdominal multidetector CT of pediatric patients. Amer. J. Roentgenol. 2002;179(5):1107–1113.
- Andria G, Attivissimo F, Lanzolla AML. A statistical approach for MR and CT images comparison. Measurement. 2013;46(7):57–65.
- Andria G, Attivissimo F, Cavone G, et al. acquisition times in magnetic resonance imaging: optimization in clinical use. IEEE Trans Instrumentation Meas. 2009;58(9):3140–3148.
- Sun J, Smith M, Smith L, et al. Simulation of an optical-sensing technique for tracking surgical tools employed in computer-assisted interventions. IEEE Sens J. 2005;5(5):1127–1131.
- Palma G, Falconi MC, Starecki F, et al. Novel double step approach for optical sensing via microsphere WGM resonance. Opt Exp. 2016;24(23):26956–26971.
- Sadjadi H, Hashtrudi-Zaad K, Fichtinger G. Simultaneous electromagnetic tracking and calibration for dynamic field distortion compensation. IEEE Trans Biomed Eng. 2016;63(8):1771–1781.
- Poulin F, Amiot LP. Interference during the use of an electromagnetic tracking system under OR conditions. J Biomechanics. 2002;35(6):733–737.
- Yaniva Z, Wilson E, Lindisch D, et al. Electromagnetic tracking in the clinical environment. Med Phys. 2009;36(3):876–892.
- Hu C, Li M, Song S, et al. A cubic 3-axis magnetic sensor array for wirelessly tracking magnet position and orientation. IEEE Sensors J. 2010;10(5):903–913
- Attivissimo F, Lanzolla AML, Carlone S, et al. TDM-FDM configuration of Electromagnetic Tracking System for Image-guided Surgery Devices, IEEE International Instrumentation and Measurement Technology Conference 2017, May 22-25, pp. 388-393, Tourin.
- IEEE Standard for Safety Levels with Respect to Human Exposure to Electromagnetic Fields, 0-3 kHz, Std. C95.6-2002.
- IEEE Standard for Safety Levels with Respect to Human Exposure to Radio requency Electromagnetic Fields, 3 kHz to 300 GHz, Std. C95.1-2005, Revision of IEEE Std C95.1-1991, 2006.
- Available from: https://www.comsol.it/
- Datasheet Northern Digital: “NI CompactDAQ - 9172”, available from: http://www.ni.com/pdf/manuals/371747f.pdf
- Datasheet Northern Digital: “NI 9263 - AO”: Available from http://www.ni.com/pdf/manuals/373781h.pdf
- NDI sensor: Available from https://www.ndigital.com/medical/products/tools-and-sensors/
- McDonald CP, Johnson JA, Peters TM, et al. Image-based navigation improves the positioning of the humeral component in total elbow arthroplasty. J Shoulder Elbow Surg. 2010;19(4):533–543.
- Adamo F, Cavone G, Di Nisio A, et al. A proposal for an open source energy meter. 2013 IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 6-9 May 2013, Minneapolis, MN, USA.
- Di Nisio A, Di Noia T, Calò Carducci CG. High dynamic range power consumption measurement in microcontroller-based applications. IEEE Trans Instrumentation Meas. 2016;65(9):1968–1976.
- Adamo F, Andria G, Bottiglieri O, et al. Instrumentation and geotechnical measurements on submarine contaminated sediments. Measurement. 2018;127:335–347.
- Xie J, Qin C, Zhou X. The simulations and experiments of the electromagnetic tracking system based on magnetic dipole model. IEEE Trans Appl Superconductivity. 2014;24(3).
- Technical manual: KUKA System Software 5.5: Available from https://www.kuka.com/it-it/prodotti-servizi/sistemi-robot/software/
- Tumanski S, Induction Coil Sensors – a Review” Measurement Science and Technology 2018, 18.
- Kindratenko VV. A survey of electromagnetic position tracker calibration techniques. Virtual Reality Res Dev Appl. 2000;5(3):169–182.