Your search keyword '"Tomažič, Sašo"' showing total 6 results

1. Online Outdoor Terrain Classification Algorithm for Wheeled Mobile Robots Equipped with Inertial and Magnetic Sensors.

Author

Sarcevic, Peter, Csík, Dominik, Pesti, Richard, Stančin, Sara, Tomažič, Sašo, Tadic, Vladimir, Rodriguez-Resendiz, Juvenal, Sárosi, József, and Odry, Akos

Subjects

MOBILE robots, MAGNETIC sensors, CLASSIFICATION algorithms, DATABASES, INFORMATION resources management, GYROSCOPES

Abstract

Terrain classification provides valuable information for both control and navigation algorithms of wheeled mobile robots. In this paper, a novel online outdoor terrain classification algorithm is proposed for wheeled mobile robots. The algorithm is based on only time-domain features with both low computational and low memory requirements, which are extracted from the inertial and magnetic sensor signals. Multilayer perceptron (MLP) neural networks are applied as classifiers. The algorithm is tested on a measurement database collected using a prototype measurement system for various outdoor terrain types. Different datasets were constructed based on various setups of processing window sizes, used sensor types, and robot speeds. To examine the possibilities of the three applied sensor types in the application, the features extracted from the measurement data of the different sensors were tested alone, in pairs and fused together. The algorithm is suitable to operate online on the embedded system of the mobile robot. The achieved results show that using the applied time-domain feature set the highest classification efficiencies on unknown data can be above 98%. It is also shown that the gyroscope provides higher classification rates than the widely used accelerometer. The magnetic sensor alone cannot be effectively used but fusing the data of this sensor with the data of the inertial sensors can improve the performance. [ABSTRACT FROM AUTHOR]

Published

2023

2. Suitability of strain gage sensors for integration into smart sport equipment

Author

Umek, Anton, Zhang, Yuan, Tomažič, Sašo, and Kos, Anton

Subjects

gyroscope, strain gage sensors, analiza golfskega zamaha, udc:621.39, golf swing analysis, pospeškometer, žiroskop, accelerometer, pametna športna oprema, sensor selection, ComputerApplications_MISCELLANEOUS, strain gage senzorji, smart sport equipment, izbira senzorjev

Abstract

Wearable devices and smart sport equipment are being increasingly used in amateur and professional sports. Smart sport equipment employs various sensors for detecting its state and actions. The correct choice of the most appropriate sensor(s) is of paramount importance for efficient and successful operation of sport equipment. When integrated into the sport equipment, ideal sensors are unobstructive, and do not change the functionality of the equipment. The article focuses on experiments for identification and selection of sensors that are suitable for the integration into a golf club with the final goal of their use in real time biofeedback applications. We tested two orthogonally affixed strain gage (SG) sensors, a 3-axis accelerometer, and a 3-axis gyroscope. The strain gage sensors are calibrated and validated in the laboratory environment by a highly accurate Qualisys Track Manager (QTM) optical tracking system. Field test results show that different types of golf swing and improper movement in early phases of golf swing can be detected with strain gage sensors attached to the shaft of the golf club. Thus they are suitable for biofeedback applications to help golfers to learn repetitive golf swings. It is suggested that the use of strain gage sensors can improve the golf swing technical error detection accuracy and that strain gage sensors alone are enough for basic golf swing analysis. Our final goal is to be able to acquire and analyze as many parameters of a smart golf club in real time during the entire duration of the swing. This would give us the ability to design mobile and cloud biofeedback applications with terminal or concurrent feedback that will enable us to speed-up motor skill learning in golf.

Published

2021

3. Suitability of Strain Gage Sensors for Integration into Smart Sport Equipment: A Golf Club Example.

Author

Umek, Anton, Yuan Zhang, Tomažič, Sašo, and Kos, Anton

Subjects

WEARABLE technology, SPORTING goods, BODY sensor networks, REAL-time computing, GAUGE field theory

Abstract

Wearable devices and smart sport equipment are being increasingly used in amateur and professional sports. Smart sport equipment employs various sensors for detecting its state and actions. The correct choice of the most appropriate sensor(s) is of paramount importance for efficient and successful operation of sport equipment. When integrated into the sport equipment, ideal sensors are unobstructive, and do not change the functionality of the equipment. The article focuses on experiments for identification and selection of sensors that are suitable for the integration into a golf club with the final goal of their use in real time biofeedback applications. We tested two orthogonally affixed strain gage (SG) sensors, a 3-axis accelerometer, and a 3-axis gyroscope. The strain gage sensors are calibrated and validated in the laboratory environment by a highly accurate Qualisys Track Manager (QTM) optical tracking system. Field test results show that different types of golf swing and improper movement in early phases of golf swing can be detected with strain gage sensors attached to the shaft of the golf club. Thus they are suitable for biofeedback applications to help golfers to learn repetitive golf swings. It is suggested that the use of strain gage sensors can improve the golf swing technical error detection accuracy and that strain gage sensors alone are enough for basic golf swing analysis. Our final goal is to be able to acquire and analyze as many parameters of a smart golf club in real time during the entire duration of the swing. This would give us the ability to design mobile and cloud biofeedback applications with terminal or concurrent feedback that will enable us to speed-up motor skill learning in golf. [ABSTRACT FROM AUTHOR]

Published

2017

4. Time- and Computation-Efficient Calibration of MEMS 3D Accelerometers and Gyroscopes.

Author

Stančin, Sara and Tomažič, Sašo

Subjects

*MICROELECTROMECHANICAL systems, *CALIBRATION, *DETECTORS, *GYROSCOPES, *ACCELEROMETERS, *MEASUREMENT

Abstract

We propose calibration methods for microelectromechanical system (MEMS) 3D accelerometers and gyroscopes that are efficient in terms of time and computational complexity. The calibration process for both sensors is simple, does not require additional expensive equipment, and can be performed in the field before or between motion measurements. The methods rely on a small number of defined calibration measurements that are used to obtain the values of 12 calibration parameters. This process enables the static compensation of sensor inaccuracies. The values detected by the 3D sensor are interpreted using a generalized 3D sensor model. The model assumes that the values detected by the sensor are equal to the projections of the measured value on the sensor sensitivity axes. Although this finding is trivial for 3D accelerometers, its validity for 3D gyroscopes is not immediately apparent; thus, this paper elaborates on this latter topic. For an example sensor device, calibration parameters were established using calibration measurements of approximately 1.5 min in duration for the 3D accelerometer and 2.5 min in duration for the 3D gyroscope. Correction of each detected 3D value using the established calibration parameters in further measurements requires only nine addition and nine multiplication operations. [ABSTRACT FROM AUTHOR]

Published

2014

5. Angle Estimation of Simultaneous Orthogonal Rotations from 3D Gyroscope Measurements.

Author

Stančin, Sara and Tomažič, Sašo

Subjects

*ROTATIONAL motion, *ANGULAR momentum (Mechanics), *GYROSCOPES, *ANGLES, *MATHEMATICAL notation

Abstract

A 3D gyroscope provides measurements of angular velocities around its three intrinsic orthogonal axes, enabling angular orientation estimation. Because the measured angular velocities represent simultaneous rotations, it is not appropriate to consider them sequentially. Rotations in general are not commutative, and each possible rotation sequence has a different resulting angular orientation. None of these angular orientations is the correct simultaneous rotation result. However, every angular orientation can be represented by a single rotation. This paper presents an analytic derivation of the axis and angle of the single rotation equivalent to three simultaneous rotations around orthogonal axes when the measured angular velocities or their proportions are approximately constant. Based on the resulting expressions, a vector called the simultaneous orthogonal rotations angle (SORA) is defined, with components equal to the angles of three simultaneous rotations around coordinate system axes. The orientation and magnitude of this vector are equal to the equivalent single rotation axis and angle, respectively. As long as the orientation of the actual rotation axis is constant, given the SORA, the angular orientation of a rigid body can be calculated in a single step, thus making it possible to avoid computing the iterative infinitesimal rotation approximation. The performed test measurements confirm the validity of the SORA concept. SORA is simple and well-suited for use in the real-time calculation of angular orientation based on angular velocity measurements derived using a gyroscope. Moreover, because of its demonstrated simplicity, SORA can also be used in general angular orientation notation. [ABSTRACT FROM AUTHOR]

Published

2011

6. Postopki za umerjanje MEMS senzorjev

Author

MODIC, ŽIGA and Tomažič, Sašo

Subjects

žiroskop, MEMS, accelerometer, gyroscope, magnetometer, Allan varianca, pospeškometer, calibration, umerjanje, Allan variance

Abstract

Diplomsko delo opisuje testiranje različnih umeritvenih postopkov inercijskih sistemov, s katerimi je možno odpraviti določene pomanjkljivosti, napake in posledično izboljšati meritev. Izvor in velikost napak je v posameznih senzorjih v večini primerov neznana, zato sem z metodo Allan varianca najprej določil karakteristiko naključnih procesov (beli šum, lezenje …). Napake senzorjev se v procesu umerjanja modelirajo z različnimi matematičnimi modeli, zato je tudi točnost in zanesljivost umeritvenih postopkov različna. V diplomskem delu sem z MIMS (SU6DOF) testiral natančnost šestih različnih umeritvenih metod pri znanih pogojih. Izmed vseh testiranih postopkov je bila najboljša in hkrati tudi najpreprostejša metoda Stančin, ki je imela za pospeškometer in žiroskop najmanjšo napako. Pri primerjavi različnih umeritvenih metod za magnetometer pa se je izkazalo, da različne metode dosegajo podobne rezultate. Izrazita je bila le razlika v velikosti napake med statično in dinamično umeritvijo magnetometra. The thesis describes testing of various calibration procedures of the magnetic inertial measurement system (MIMS), with which certain deficiencies, and errors can be eliminated, and consequently measurement can be improved. Errors of individual sensors are in most of the cases unknown, therefore, I first determined the characteristics of random processes (white noise, drift etc.) using the Allan variance method. Every sensor has its own errors that are modelled in the process of calibration with an appropriate numerical model. Therefore, the accuracy and reliability of calibration procedures is different. The performance of six different calibration procedures in known conditions was empirically evaluated using a commercially available MIMS (SU6DOF). A series of tests for accelerometer and gyroscopes have shown that the best method in terms of accuracy, simplicity, and errors was presented by Stančin. A comparison of various calibration methods for a magnetometer however, showed no difference in total average error. Only a difference in the size of the error among the static and dynamic calibration of magnetometer was distinct.

Published

2016