Abstract :
In characterizing the bandwidth of measurement devices used in ultrasound exposimetry, attention has been focused on the high frequency response. However, current diagnostic ultrasound measurement standards have low frequency specifications for hydrophones and associated amplifiers, and the response below 1 MHz can be especially significant when measuring lithotripsy pulses. To model the effects of diminished low frequency response, simulated diagnostic and lithotripsy pulses were filtered with a single-pole high-pass filter for a range of -3 dB cutoff frequencies (denoted fa). For lithotripsy pulses it was found that the pulse quantities peak rarefactional pressure (pr) and pulse width (tw) were most sensitive to fa, and to keep errors in pr and tw below 10%, fa should be in the 10-60 kHz range for the pulses examined. For the diagnostic case, pr was the quantity most significantly affected, and for an fa value approximately one-half the center frequency, pr was decreased by more than 30% for a pulse modeled to show the effects of finite amplitude distortion typical of diagnostic pulses measured in water. Given this latter result, current hydrophone and amplifier low frequency specifications may need to be reconsidered
Keywords :
acoustic filters; acoustic pulses; biomedical ultrasonics; dosimetry; high-pass filters; hydrophones; radiation therapy; 10 to 60 kHz; amplifier low frequency specifications; bandwidth; cutoff frequencies; diagnostic ultrasound measurement standards; diminished low frequency response; finite amplitude distortion; high frequency response; hydrophones; lithotripsy pulses; low frequency specifications; peak rarefactional pressure; pressure pulse distortion; pulse width; simulated diagnostic pulses; single-pole high-pass filter; ultrasound exposimetry; water; Acoustic filters; Acoustic pulses; Biomedical acoustic imaging; Biomedical applications of acoustic radiation; Biomedical transducers; High-pass filters; Hydrophones; Radiation detectors;
