FI simulation with a moving point scatterer on a phased array with the USTB built-in Fresnel simulator
In this example we show how to use the built-in fresnel simulator in USTB to generate a Conventional Focused Imaging (single focal depth) dataset for a phased array and a sector scan and how it can be beamformed with USTB. Specifically, in this example, a point scatterer under study moves between acquired frames.
This tutorial assumes familiarity with the contents of the 'CPWC simulation with the USTB built-in Fresnel simulator' tutorial. Please feel free to refer back to that for more details.
by Alfonso Rodriguez-Molares alfonso.r.molares@ntnu.no, Ole Marius Hoel Rindal olemarius@olemarius.net and Arun Asokan Nair anair8@jhu.edu 11.03.2017
Contents
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Phantom
The fresnel simulator takes a phantom structure as input. phantom is an Ultrasound File Format (UFF) structure that contains the position of a of a point scatterer(s). USTB's implementation of phantom includes a plot method Below, we only deal with a single point scatterer. We can change N_sca to have multiple point scatterers, and have to add the appropriate additional information below.
N_sca=1; % number of scatterers x_sca=-20e-3; % azimuthal position of scatterer(s) [m] z_sca=30e-3; % axial position of scatterer(s) [m] p=[x_sca zeros(N_sca,1) z_sca]; % matrix of scatterer position vectors N_frames=5; % number of frames N_beams=128; % number of focused beams alpha=35*pi/180; % scatterer direction [rad] v_mag=0.25; % scatterer velocity magnitude [m/s] v=v_mag*ones(N_sca,1)*[cos(alpha) 0 sin(alpha)]; % scatterer velocity [m/s m/s m/s] PRF=4000; % pulse repetition frequency [Hz] fig_handle=figure(); for n=1:N_frames*N_beams pha(n)=uff.phantom(); pha(n).sound_speed=1540; % speed of sound [m/s] pha(n).points=[p+v*(n-1)/PRF, ones(N_sca,1)]; % point scatterer position [m] pha(n).plot(fig_handle); end
Probe
The next UFF structure we look at is probe. It contains information about the probe's geometry. USTB's implementation of probe comes with a plot method too. When combined with the previous figure we can see the position of the probe respect to the phantom.
prb=uff.linear_array(); prb.N=64; % number of elements prb.pitch=300e-6; % probe pitch in azimuth [m] prb.element_width=270e-6; % element width [m] prb.element_height=7000e-6; % element height [m] prb.plot(fig_handle);
Pulse
We then define the pulse-echo signal which is done here using the fresnel simulator's pulse structure. We could also use 'Field II' for a more accurate model.
pul=uff.pulse(); pul.center_frequency=3e6; % transducer frequency [MHz] pul.fractional_bandwidth=0.6; % fractional bandwidth [unitless] pul.plot([],'2-way pulse');
Sequence generation
Now, we shall generate our sequence! Keep in mind that the fresnel simulator takes the same sequence definition as the USTB beamformer. In UFF and USTB a sequence is defined as a collection of wave structures.
For our example here, we define a sequence of 128 (= N_beams) focused beams spanning an azimuthal angular range of ![$[-\frac{35\pi}{180},\frac{35\pi}{180} ]$](FI_phased_array_multiframe_eq10357469457311710108.png)
radians. The focal depth is set as 40 mm. The wave structure too has a plot method.
azimuth_axis=linspace(-35*pi/180,35*pi/180,N_beams).'; % beam angle vector [rad] depth=40e-3; % fixed focal depth [m] seq=uff.wave(); for n=1:N_beams seq(n)=uff.wave(); seq(n).probe=prb; seq(n).source=uff.point(); seq(n).source.azimuth=azimuth_axis(n); seq(n).source.distance=depth; seq(n).apodization=uff.apodization(); seq(n).apodization.window=uff.window.tukey50; seq(n).apodization.f_number=1.7; seq(n).apodization.focus=uff.sector_scan('xyz',seq(n).source.xyz); seq(n).sound_speed=pha.sound_speed; % show source fig_handle=seq(n).source.plot(fig_handle); end
The Fresnel simulator
Finally, we launch the built-in simulator. The simulator takes in a phantom, pulse, probe and a sequence of wave structures along with the desired sampling frequency, and returns a channel_data UFF structure.
sim=fresnel(); % setting input data sim.phantom=pha; % phantom sim.pulse=pul; % transmitted pulse sim.probe=prb; % probe sim.sequence=seq; % beam sequence sim.sampling_frequency=41.6e6; % sampling frequency [Hz] % we launch the simulation channel_data=sim.go();
USTB's Fresnel impulse response simulator (v1.0.7) ---------------------------------------------------------------
Scan
The scan area is defines as a collection of pixels spanning our region of interest. For our example here, we use the sector_scan structure to generate a sector scan. scan too has a useful plot method it can call.
depth_axis=linspace(5e-3,80e-3,256).'; scan=uff.sector_scan('azimuth_axis',azimuth_axis,'depth_axis',depth_axis);
Midprocess
With channel_data and a scan we have all we need to produce an ultrasound image. We now use a USTB structure midprocess, that takes an apodization structure in addition to the channel_data and scan, and returns a beamformed_data.
mid=midprocess.das(); mid.channel_data=channel_data; mid.scan=scan; mid.dimension = dimension.both(); mid.transmit_apodization.window = uff.window.scanline; mid.receive_apodization.window=uff.window.tukey50; mid.receive_apodization.f_number=1.7; b_data=mid.go();
USTB General beamformer MEX v1.1.2 .............done!
Plotting the data
The below plot method shows an interactive window in which we can play the multiple frames as a movie.
b_data.plot();
