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Digitally controlled power amplifier for underwater electro acoustic transducers

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Abstract:

A digitally controlled sonar power amplifier for underwater transmitter is explained in this paper. It proposes a method of generating unipolar Sine Pulse Width Modulatio...Show More

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Abstract:

A digitally controlled sonar power amplifier for underwater transmitter is explained in this paper. It proposes a method of generating unipolar Sine Pulse Width Modulation (SPWM) signals for echo ranging sonar. This method can be effectively used in all kinds of inverters including high frequency inverters. A low cost digital signal controller was used to generate SPWM signals and used as gating pulses for a Controlled Full Bridge Circuit (CFBC). The power required, frequency, pulse-width and pulse repetition interval are given as the inputs to the digital controller and gating pulses for the CFBC are generated as output from the controller. A power transformer connected across CFBC boosts output voltage followed by power filter which removes unwanted harmonics present in the output. The output after the power filter is used to excite electro-acoustic transducer elements underwater. The voltage and current of the load were given as feedback to the same controller for voltage mode control loop implementation of the system. A prototype of 1kW Switch Mode Power Amplifier (SMPA) for echo ranging sonar has been designed and digital control has been implemented. Salient results are presented.

Published in: 2016 3rd International Conference on Signal Processing and Integrated Networks (SPIN)

Date of Conference: 11-12 February 2016

Date Added to IEEE Xplore: 15 September 2016

ISBN Information:

DOI: 10.1109/SPIN.2016.7566709

Conference Location: Noida, India

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Contents

I. Introduction

ELECTRO acoustic transducers convert electrical energy into acoustic energy and vice versa. They find many application and very instrumental in underwater acoustic where it is used for the detection of objects under the sea. It is also used in seismic exploration, detection of depth of the sea and oil exploration industry. SOund Navigation And Ranging (SONAR) device is used for the above purpose and power amplifier is an integral part of SONAR system. A short duration of pulse is given to electro acoustic projectors and an echo returned from the object is used to find out the range of the object in sonar system. The signals most commonly used in echo-ranging systems are Continuous Wave (CW), Linear Frequency Modulation (LFM), and Pseudo Random Noise (PRN) etc. The signal(s) selected would depend upon the particular application, and the operational and hardware constraints [1].

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Alan A Winder, "Sonar System Technology", IEEE Transactons On Sonics And Ultrasonics, vol. Su-22, no. 5, pp. 291-331, September 1975.

View Article

Google Scholar

A.D Waite, "Sonar for practising Engineers", Wiley Publications, 2002.

Google Scholar

R. Coates and Sciche, "The Sonar Course", Seiche Technical Education, 2003.

Google Scholar

Wallenhauer Carsten, Gottlieb Bernhard, Z. Roland and Andreas Kappel, "Efficiency Improved High-Voltage Analog Power Amplifier for Driving Piezoelectric Actuators", IEEE Transactions On Circuits And Systems—I: Regular Papers, vol. 57, no. 1, pp. 291-298, January 2010.

Google Scholar

C. Baylis, L. Wang, M. Moldovan, J. Martin, H. Miller, L. Cohen, et al., "Designing transmitters for spectral conformity: power amplifier design issues and strategies", IET Radar Sonar Navig., vol. 5, no. 6, pp. 681-685, 2011.

CrossRef Google Scholar

David M. J. Cowell, Peter R. Smith and Steven Freear, "Harmonic Cancellation in Switched Mode Linear Frequency Modulated (LFM) Excitation of Ultrasound Arrays", IEEE International Ultrasonics Symposium Proceedings, pp. 454-457, 2011.

CrossRef Google Scholar

Kenle Chen, Xiaogu and Liuand Dimitrios Peroulis, "Widely Tunable High-Efficiency Power Amplifier With Ultra-Narrow Instantaneous Bandwidth", IEEE Transactions on Microwave Theory And Techniques, vol. 60, no. 12, pp. 3787-3797, Dec 2012.

View Article

Google Scholar

Michael Karpelson, Gu-Yeon Wei and Robert J. Wood, "Driving high voltage piezoelectric actuators in microrobotic applications", Sens. Actuators A: Phys., 2012, [online] Available: http://10.1016/j.sna.2011.11.035.

CrossRef Google Scholar

N. Mohan, T. M. Undeland and W. P. Robbins, PowerElectronics-Converters Applications and Design, New Delhi:John Wiley & SonsInc., pp. 200-217, 2010.

Google Scholar

10.

D, C. Kalbfell, "Power Amplifiers for Underwater Transducers", IEEE Conf. on Engg. in Ocean Environment, Sept. 1973.

View Article

Google Scholar

11.

K. Agbossou, J. Dion, S. Carignan, M. Abdelkrim and A. Cheriti, "Class D Amplifier for A Power Piezoelectric Load", IEEE Trans. On Ultrasonics Ferroelectrics and Frequency Control, vol. 47, no. 4, pp. 1036-1041, July 2000.

View Article

Google Scholar

12.

Sreekumar, V Anand, N Panchalai, Bineesh P Chacko and Preethi Thekkath, "Multilevel converter for excitation of underwater transducers", Advances in Computing Communications and Informatics (ICACCI) 2015 International Conference on., 2015.

Google Scholar

13.

"PWM low pass filtering Applications Note 32" in , USA:Inc, vol. 12, pp. 750-759, 2005.

Google Scholar

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Digitally controlled power amplifier for underwater electro acoustic transducers

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