Owing to the highly maneuvering character involved in targets, the nonuniform 3-D rotation
motions make the assumption that the image projection plane (IPP) is constant during …

An important challenge in high-resolution inverse synthetic aperture radar (ISAR) imaging of
maneuvering targets is the 2-D spatial-variant (SV) high-order phase error. The classic …

For inverse synthetic aperture radar (ISAR) imaging of the maneuvering target, when the
time-varying rotational acceleration arises, the image will become blurred because of high …

When a target is involved in maneuvering motion, the nonuniform 3-D rotation motion will
cause a continuous change of image projection plane (IPP), which would induce 2-D spatial …

Translational motion compensation constitutes a pivotal and essential procedure in inverse
synthetic aperture radar (ISAR) imaging. Many researchers have previously proposed their …

The existing inverse synthetic aperture radar (ISAR) imaging algorithms for ship targets with
complex three-dimensional (3D) rotational motion are not applicable because of continuous …

Bistatic inverse synthetic aperture radar (Bi-ISAR) can obtain complementary information
about moving targets and overcome the inherent imaging limitations of monostatic ISAR …

For spaceborne ISAR imaging of space targets, due to the high-speed relative motion
between the radar and targets, both the translational and rotational motion exhibit the high …

Inverse synthetic aperture radar (ISAR) imaging for maneuvering targets has always been a
challenging task due to azimuth time-varying Doppler frequency modulation, especially …

When a target is moving at high-speed, its high-resolution range profile (HRRP) will be
stretched by the high-order phase error caused by the high velocity. In this case, the inverse …