RESUMO
Tonpilz transducers are desirable for their superior performance in underwater target detection and communication applications. Several design schemes to widen their bandwidth have been reported, but these schemes often involve a complex structure or arrangement of additional components. In this study, a simple design is proposed to improve the bandwidth of a multimode Tonpilz transducer by using a non-uniform drive section that consists of piezoelectric stacks of various thicknesses. The efficacy of the design is illustrated with a multimode Tonpilz transducer having three lead zirconate titanate (PZT) stacks of different thicknesses. A new equivalent circuit was developed to analyze the frequency response of the transducer incorporating the non-uniform drive section and was used for rigorous analysis of the effects of varying the position and thickness of the non-uniform stacks on the transmitting characteristics of the transducer. The validity of the design was verified through the fabrication and characterization of a prototype multimode Tonpilz transducer. The developed structure can be readily extended to an arbitrary number of stacks in the Tonpilz transducer with any number of PZT disks in each stack.
RESUMO
Typical underwater Tonpilz transducers detect the magnitude of an acoustic pressure, a scalar quantity, by means of piezoceramic rings, and convert this pressure into a proportional electric voltage. The scalar sensor has no directional sensitivity. This paper proposes a new vector sensor based on the Tonpilz transducer that is sensitive to both the magnitude and direction of an incoming acoustic wave. The piezoceramic rings of the new Tonpilz-type vector sensor are divided into four quadrant segments. The direction of an incoming acoustic wave is identified by combining the output voltages of the four piezoceramic segments in a particular manner. The operation frequency range of the vector sensor follows that of conventional Tonpilz transducers. The feasibility of this new structural design has been confirmed through a three-dimensional simulation of the operation of the vector sensor with the finite element method. The validity of the new design is verified by fabricating and characterizing an experimental prototype of the vector sensor.
RESUMO
INTRODUCTION: The purposes of this study were to compare the asymmetry index using panoramic radiography and cone-beam computed tomography for detecting mandibular posterior asymmetry and to evaluate the diagnostic value of the asymmetry index on panoramic radiography. METHODS: A total of 43 patients were included in this study. Ten mandibular posterior distances were measured using panoramic radiography and cone-beam computed tomography, and 10 asymmetry index values were calculated. The reliability of each asymmetry index was assessed. For evaluating validity of each asymmetry index using panoramic radiography, the paired t test and the Bland-Altman analysis were used. The accuracy of the asymmetry index and the area under the curve of receiver operator characteristic were calculated. RESULTS: The asymmetry index of total ramal height showed good reliability (ICC, >0.888). In condylar height 1, specificity and negative predictive value were low (0.08 and 0.17, respectively), 95% limits of agreement were ±17.9%, and area under the curve was 0.484. In total, ramal height accuracy was 0.86, and areas under the curve were 0.926 to 0.957. CONCLUSIONS: For detecting asymmetry of the condyle region, the asymmetry index using panoramic radiography had little diagnostic value, and we recommend using cone-beam computed tomography images. However, the asymmetry index for total ramal height showed good reliability and relatively higher validity, and its diagnostic value was excellent.