Abstract
Therapeutic ultrasound is an emerging field with many medical applications. High intensity focused ultrasound provides the ability to localize the deposition of acoustic energy within the body, which can cause tissue necrosis and hemostasis. The ultrasound applied in therapy is usually ranged from 1MHz to 1000MHz. Even the least vibration of 1MHz would be as keen as a sharp knife to cut off steels, if we reinforce its amplitude. However, the output of the ultrasound used in treating people must be decreased substantially. A specific increase in temperature is necessary to achieve a temperature-mediated therapeutic impact by ultrasound in rehabilitation. On a large scale ultrasound intensity determines the temperature level on the tissue. High intensity causes a marked mechanical peak loading of the tissue. This may even lead to tissue damage. The extreme pressure differences developing as a consequence of exposure to ultrasound may cause cavitations in the tissues. Opinions in the literature on the duration of treatment also vary. The duration of treatment depends on the size of the body area to be treated. Lehmann fixes the maximum duration of treatment at 15 minutes. This refers to a treated area of 75–100 cm2 which he considers the maximum area that can reasonably be treated. New medical applications have required advances in biomedical equipment design and advances in numerical and experimental studies of the interaction of sound with biological tissues and fluids. In this study a fuzzy logic control system will be explained which was developed in order to obtain optimum ultrasound intensity and determine optimum treatment time during ultrasound therapy (UT). This system also increases patient safety and comfort during UT.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Conradi E, (1982) ‘Zum gegenw→tigen Stand der Therapie mit Impulsultraschall’. Zeitschrift für Physiotherapie, pp 286, 371–376.
Conradi E, Fritze U, Hoffmann B, (1983) ‘Untersuchungen zur Verteilung der Wärmeenergie in verschiedenen Gewebsschichten beim Schwein nach Ultraschalltherapie im Gleich-und Impulsbetrieb’. Zeitschrift für Physiotherapie, 35, pp 271–280.
Daniel S, Prince DJ, (1992) Sonoluminesce in water agar gels during irradiation with 0,75 MHz continuous-wave ultrasound, IEEE International Conference, pp 297–308.
Daniel S, Kodoma T, Prince DJ, (1995) Ultrasound in medicine and Biology, IEEE Biomedical Engineering, V.21, pp 105–111.
De Lisa JA, Gans M, (1993) Rehabilitation Medicine Principles and Practice, Second Edition, pp 408–410.
Edel H en A. Lange (1979) ‘Schmerzmodulation durch elektrische Reize und Ultraschall’. Zeitschrift für Physiotherapie, 31, 4.
Enraf Nonius, (1996) Ultrasound Therapy, june, The Netherlands.
Lehmann JF, (1982) Therapeutic Heat and cold, 3e druk. Williams and Wilkins Baltimore, London
Payton OD, Lamp RL, Kasey ME, (1975) ‘Effects on therapeutic ultrasound on bone marrow in dogs’. Physical therapy, USA, pp 20–27.
Pohlman R, (1951) Die Ultraschalltherapie, Verlag Hans Huber, Bern.
Shriber WJ, (1975) A manual of electrotherapy. Philadelphia, pp 339–342.
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2005 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Yardimci, A., Celik, O. (2005). Ultrasound Intensity and Treatment Time Fuzzy Logic Control System for Low Cost Effective Ultrasound Therapy Devices. In: Reusch, B. (eds) Computational Intelligence, Theory and Applications. Advances in Soft Computing, vol 33. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-31182-3_75
Download citation
DOI: https://doi.org/10.1007/3-540-31182-3_75
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-22807-3
Online ISBN: 978-3-540-31182-9
eBook Packages: EngineeringEngineering (R0)