Supplementary Movie 6.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 6: Reconstructed video of a 30-slot optical chopper rotating at 4800 RPM (9.83 ms duration, 11×13 frame size, 12.0 kfps framerate, 55% sampling), corresponding to the data presented in (from left to right) Fig. 6b–f. </p

Supplementary Movie 1.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 1: Three reconstructed videos of an oscillating pendulum (1.53 s duration, 41×43 frame size), corresponding to the data presented in Fig. 3. Sampling rates (from left to right) are 100%, 50%, and 25%, with imaging speeds of 145 fps, 298 fps, and 598 fps, respectively.  </p

Supplementary Movie 5.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 5: Reconstructed video of the current-induced failure of an exposed incandescent light bulb filament (1.79 s duration, 41×43 frame size, 298 fps framerate, 50% sampling), corresponding to the data presented in Fig. 5e.  </p

Supplementary Movie 7.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 7: Filmed demonstration of SPI-ASAP operating in real-time for a variety of scenes, frame sizes, and frame rates. </p

Supplementary Movie 4.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 4: Reconstructed video of the current-induced failure of a sealed incandescent light bulb filament (1.06 s duration, 41×43 frame size, 298 fps framerate, 50% sampling), corresponding to the data presented in Fig. 5b. </p

Supplementary Movie 2.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 2: Reconstructed video of the mechanical watch movement (2.20 s duration, 59×61 frame size, 103 fps framerate, 100% sampling), corresponding to the data presented in Fig. 4b.</p

Supplementary Movie 3.mp4

Kilcullen, P., Ozaki, T. & Liang, J. Compressed ultrahigh-speed single-pixel imaging by swept aggregate patterns. Nat Commun 13, 7879 (2022). https://doi.org/10.1038/s41467-022-35585-8 Supplementary Movie 3: Reconstructed video of a rupturing popcorn kernel (0.89 s duration, 41×43 frame size, 298 fps framerate, 50% sampling), corresponding to the data presented in Fig. 4e.</p

Schematic diagram of a FD-LCI system.

<p>Schematic diagram of a FD-LCI system.</p

Eye movement at the macula and optic disk region was investigated for the three subject groups.

<p>In (a) are compared the effective amplitude of the movement, in (b) the FFT integrated amplitude ratio between the movement fundamental frequency and the movement second harmonic, in (c) the phase shift between the movement fundamental frequency with respect to the oximeter signal fundamental frequency, and in (d) the phase shift between the movement second harmonic with respect to movement fundamental frequency.</p

Representative data and movement analysis.

<p>(a) Typical A-scan produced by the retina where the nerve fiber layer (NFL) and retinal pigment epithelium (RPE) are clearly observed. (b) Position of the retina in the macula region as a function of time along with oximeter signal, as recorded by the SD-LCI for a 30-years-old normal female subject. Movement and oximeter signal FFT analysis are shown in (c) and (d).</p