This work is licensed under the Creative Commons Attribution 4.0 International License.
N. FERENČíK, M. JAŠČUR, M. BUNDZEL, and F. CAVALLO. The rehapiano—detecting, measuring, and analyzing action tremor using strain gauges. Sensors, 20(3):663, 2020.Search in Google Scholar
Iris JAKOB, Alexander KOLLREIDER, Marco GERMANOTTA, Filippo BENETTI, Arianna CRUCIANI, Luca PADUA, and Irene APRILE. Robotic and sensor technology for upper limb rehabilitation. PM&R, 10:S189–S197, 2018.Search in Google Scholar
Daniele CAFOLLA, Matteo RUSSO, and Giuseppe CARBONE. Cube, a cable-driven device for limb rehabilitation. Journal of Bionic Engineering, 16(3):492–502, 2019.Search in Google Scholar
ALMUSAWI Husam ABDUL Kareem, Afghan Syeda ADILA, and Géza HUSI. Recent trends in robotic systems for upper-limb stroke recovery: A low-cost hand and wrist rehabilitation device. In 2018 2nd international symposium on small-scale intelligent manufacturing systems (sims), pages 1–6. IEEE, 2018.Search in Google Scholar
Ana MANDELJC, Aleksander RAJHARD, Marko MUNIH, and Roman KAMNIK. Robotic device for out-of-clinic post-stroke hand rehabilitation. Applied Sciences, 12(3):1092, 2022.Search in Google Scholar
Raphael RÄTZ, François CONTI, René M Müri, and Laura Marchal-Crespo. A novel clinical-driven design for robotic hand rehabilitation: Combining sensory training, effortless setup, and large range of motion in a palmar device. Frontiers in neurorobotics, 15, 2021.Search in Google Scholar
JW JOO, KS NA, and DI KANG. Design and evaluation of a six-component load cell. Measurement, 32(2):125–133, 2002.Search in Google Scholar
Ivan MULLER, Renato Machado de BRITO, Carlos Eduardo PEREIRA, and Valner BRUSAMARELLO. Load cells in force sensing analysis–theory and a novel application. IEEE Instrumentation & Measurement Magazine, 13(1):15–19, 2010.Search in Google Scholar
Michel SJ STEYAERT and Willy MC SANSEN. A micropower low-noise monolithic instrumentation amplifier for medical purposes. IEEE journal of solid-state circuits, 22(6):1163–1168, 1987.Search in Google Scholar
Pervez M AZIZ, Henrik V SORENSEN, and J Van der SPIEGEL. An overview of sigma-delta converters. IEEE signal processing magazine, 13(1):61–84, 1996.Search in Google Scholar
Mark HALLETT. Parkinson’s disease tremor: patho-physiology. Parkinsonism & related disorders, 18:S85–S86, 2012.Search in Google Scholar
Kathe S PEREZ, Lorraine Olson RAMIG, Marshall E SMITH, and Christopher DROMEY. The parkinson larynx: tremor and videostroboscopic findings. Journal of Voice, 10(4):354–361, 1996.Search in Google Scholar
Christian R BAUMANN. Epidemiology, diagnosis and differential diagnosis in parkinson’s disease tremor. Parkinsonism & related disorders, 18:S90–S92, 2012.Search in Google Scholar
Mark HALLETT. Tremor: pathophysiology. Parkinsonism & related disorders, 20:S118–S122, 2014.Search in Google Scholar
Joseph JANKOVIC, Kenneth S SCHWARTZ, and William ONDO. Re-emergent tremor of parkinson’s disease. Journal of Neurology, Neurosurgery & Psychiatry, 67(5):646–650, 1999.Search in Google Scholar
F GHIKA-SCHMID, J GHIKA, F REGLI, and J BOGOUSSLAVSKY. Hyperkinetic movement disorders during and after acute stroke: the lausanne stroke registry. Journal of the neurological sciences, 146(2):109–116, 1997.Search in Google Scholar
Raja MEHANNA and Joseph JANKOVIC. Movement disorders in cerebrovascular disease. The Lancet Neurology, 12(6):597–608, 2013.Search in Google Scholar
Pamela W DUNCAN, Larry B GOLDSTEIN, Ronnie D HORNER, Pamela B LANDSMAN, Gregory P SAMSA, and David B MATCHAR. Similar motor recovery of upper and lower extremities after stroke. Stroke, 25(6):1181–1188, 1994.Search in Google Scholar
F ALARCÓN, JCM ZIJLMANS, G DUENAS, and N CEVALLOS. Post-stroke movement disorders: report of 56 patients. Journal of Neurology, Neuro-surgery & Psychiatry, 75(11):1568–1574, 2004.Search in Google Scholar
Jong S KIM. Delayed onset mixed involuntary movements after thalamic stroke: clinical, radiological and pathophysiological findings. Brain, 124(2):299–309, 2001.Search in Google Scholar
Alexandra HANDLEY, Pippa MEDCALF, Kate HELLIER, and Dipankar DUTTA. Movement disorders after stroke. Age and ageing, 38(3):260–266, 2009.Search in Google Scholar
Lutfiye DURAK and Orhan ARIKAN. Short-time fourier transform: two fundamental properties and an optimal implementation. IEEE Transactions on Signal Processing, 51(5):1231–1242, 2003.Search in Google Scholar
Michael PORTNOFF. Time-frequency representation of digital signals and systems based on short-time fourier analysis. IEEE Transactions on Acoustics, Speech, and Signal Processing, 28(1):55–69, 1980.Search in Google Scholar
Henry K KWOK and Douglas L JONES. Improved instantaneous frequency estimation using an adaptive short-time fourier transform. IEEE transactions on signal processing, 48(10):2964–2972, 2000.Search in Google Scholar
Jingang ZHONG and Yu HUANG. Time-frequency representation based on an adaptive short-time fourier transform. IEEE Transactions on Signal Processing, 58(10):5118–5128, 2010.Search in Google Scholar
Mehmet Rahmi CANAL. Comparison of wavelet and short time fourier transform methods in the analysis of emg signals. Journal of medical systems, 34(1):91–94, 2010.Search in Google Scholar
Abdelghani DJEBBARI and F Bereksi REGUIG. Short-time fourier transform analysis of the phonocardiogram signal. In ICECS 2000. 7th IEEE International Conference on Electronics, Circuits and Systems (Cat. No. 00EX445), volume 2, pages 844–847. IEEE, 2000.Search in Google Scholar
M Kemal KıYMıK, ˙Inan GÜLER, Alper DIZIBÜYÜK, and Mehmet AKıN. Comparison of stft and wavelet transform methods in determining epileptic seizure activity in eeg signals for real-time application. Computers in biology and medicine, 35(7):603–616, 2005.Search in Google Scholar
Kevin ENGLEHART, Bernard HUDGINS, Philip A PARKER, and Maryhelen STEVENSON. Classification of the myoelectric signal using time-frequency based representations. Medical engineering & physics, 21(6-7):431–438, 1999.Search in Google Scholar
Muhammad HUZAIFAH. Comparison of time-frequency representations for environmental sound classification using convolutional neural networks. arXiv preprint arXiv:1706.07156, 2017.Search in Google Scholar
Jingshan HUANG, Binqiang CHEN, Bin YAO, and Wangpeng HE. Ecg arrhythmia classification using stft-based spectrogram and convolutional neural network. IEEE access, 7:92871–92880, 2019.Search in Google Scholar
Shalu CHAUDHARY, Sachin TARAN, Varun BAJAJ, and Abdulkadir SENGUR. Convolutional neural network based approach towards motor imagery tasks eeg signals classification. IEEE Sensors Journal, 19(12):4494–4500, 2019.Search in Google Scholar
Alan V OPPENHEIM and Ronald W SCHAFER. From frequency to quefrency: A history of the cepstrum. IEEE signal processing Magazine, 21(5):95–106, 2004.Search in Google Scholar
Donald G CHILDERS, David P SKINNER, and Robert C KEMERAIT. The cepstrum: A guide to processing. Proceedings of the IEEE, 65(10):1428–1443, 1977.Search in Google Scholar
R KEMERAIT and D CHILDERS. Signal detection and extraction by cepstrum techniques. IEEE transactions on information theory, 18(6):745–759, 1972.Search in Google Scholar
Stanislav HUSÁR, Norbert FERENČíK, Marek BUNDZEL, and Slavomír KARDOŠ. Design and evaluation of the electronic sensing system of rehapiano. In 2022 IEEE 20th Jubilee World Symposium on Applied Machine Intelligence and Informatics (SAMI), pages 000279–000284. IEEE, 2022.Search in Google Scholar
