Abstract
In this paper a method for designing waveforms
for temporal encoding in medical ultrasound imaging
is described. The method is based on least squares optimization
and is used to design nonlinear frequency modulated
signals for synthetic transmit aperture imaging. By
using the proposed design method, the amplitude spectrum
of the transmitted waveform can be optimized, such that
most of the energy is transmitted where the transducer has
large amplification. To test the design method, a waveform
was designed for a BK8804 linear array transducer. The resulting
nonlinear frequency modulated waveform was compared
to a linear frequency modulated signal with amplitude
tapering, previously used in clinical studies for synthetic
transmit aperture imaging. The latter had a relatively
flat spectrum which implied that the waveform tried
to excite all frequencies including ones with low amplification.
The proposed waveform, on the other hand, was designed
so that only frequencies where the transducer had a
large amplification were excited. Hereby, unnecessary heating
of the transducer could be avoided and the signal-tonoise
ratio could be increased. The experimental ultrasound
scanner RASMUS was used to evaluate the method experimentally.
Due to the careful waveform design optimized
for the transducer at hand, a theoretic gain in signal-tonoise
ratio of 4.9 dB compared to the reference excitation
was found, even though the energy of the nonlinear frequency
modulated signal was 71% of the energy of the reference
signal. This was supported by a signal-to-noise ratio
measurement and comparison in penetration depth, where
an increase of 1 cm was found in favor for the proposed
waveform. Axial and lateral resolutions at full-width halfmaximum
were compared in a water phantom at depths
of 42, 62, 82, and 102 mm. The axial resolutions of the
nonlinear frequency modulated signal were 0.62, 0.69, 0.60,
and 0.60 mm, respectively. The corresponding axial resolutions
for the reference waveform were 0.58, 0.65, 0.62, and
0.60 mm, respectively. The compression properties of the
matched filter (mismatched filter for the linear frequency
modulated signal) were tested for both waveforms in simulation
with respect to the Doppler frequency shift occurring
when probing moving objects. It was concluded that
the Doppler effect of moving targets does not significantly
degrade the filtered output. Finally, in vivo measurements
are shown for both methods, wherein the common carotid
artery on a 27-year-old healthy male was scanned
Original language | English |
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Journal | IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control |
Volume | 54 |
Issue number | 10 |
Pages (from-to) | 2070-2081 |
ISSN | 0885-3010 |
DOIs | |
Publication status | Published - 2007 |