Medical Ultrasound Imaging
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Searchterm 'BandWidth' found in 9 articles
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Pulse Inversion Imaging
(PII) Pulse inversion imaging (also called phase inversion imaging) is a non-linear imaging method specifically made for enhanced detection of microbubble ultrasound contrast agents. In PII, two pulses are sent in rapid succession into the tissue; the second pulse is a mirror image of the first. The resulting echoes are added at reception. Linear scattering of the two pulses will give two echoes which are inverted copies of each other, and these echoes will therefore cancel out when added.
Linear scattering dominates in tissues. Echoes from linear scatterers such as tissue cancel, whereas those from gas microbubbles do not. Non-linear scattering of the two pulses will give two echoes which do not cancel out completely due to different bubble response to positive and negative pressures of equal magnitude. The harmonic components add, and the signal intensity difference between non-linear and linear scatterers is therefore increased. The resulting images show high sensitivity to bubbles at the resolution of a conventional image.
In harmonic imaging, the frequency range of the transmitted pulse and the received signal should not overlap, but this restriction is less in pulse inversion imaging since the transmit frequencies are not filtered out, but rather subtracted. Broader transmit and receive bandwidths are therefore allowed, giving shorter pulses and improved axial resolution, hence the alternative term wideband harmonic imaging. Many ultrasound machines offer some form of pulse inversion imaging.

See also Pulse Inversion Doppler, Narrow Bandwidth, Dead Zone, Ultrasound Phantom.
Hydrophone
A hydrophone is a special transducer for underwater measurement of acoustic fields. The diameter of a hydrophone should be smaller than the wavelength of the measured ultrasound, in combination with a large bandwidth.
Image Quality
The perfect image quality is dependent on some assumptions of the propagation of ultrasound waves in tissues after generating in an imaging system. These assumptions are important for the developing of optimal ultrasound imaging systems.
The sound velocity in the examined tissue is homogeneous and constant (around 1540 m/s).
The propagation of ultrasound is straight ahead.
The ultrasound beam is infinite thin in its thickness and lateral direction.
The detected echo comes from the shortest sound path between reflector and transducer.
The ultrasound echo is originated by the last generated sound pulse.
The amplitudes of the echoes are proportional to the difference of the acoustical impedance caused by different tissue layers.
A lot of steps can be taken to prevent artifacts and to improve image quality, for example beamforming is used to focus the ultrasound beam, and contrast agents decrease the reflectivity of the undesired interfaces or increase the backscattered echoes from the desired regions.

See also Coded Excitation, Validation and Refraction Artifact, Q-Value, Ultrasound Phantom, Dead Zone, Narrow Bandwidth.
Spectral Broadening
Spectral broadening widens the bandwidth of the returning Doppler shifted signal due to its interaction with scatterers traveling at different velocities. This can be seen with turbulent or disturbed flow distal to an arterial stenosis.
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 [last update: 2023-11-06 01:42:00]