Sentence examples for imaging sense from inspiring English sources

Imaging was performed with single-shot echo planar imaging in combination with parallel imaging (SENSE factor 2.5) and background suppression.

Scan parameters included: velocity encoding (VENC) = 100 cm/s, flip angle = 8°, echo time = 3.7 ms, repetition time = 6.3 ms, parallel imaging (SENSE) speed-up factor = 2, and k-space segmentation factor = 2.

From all subjects 2 sets of 30 weighted diffusion scans and 5 unweighted B0 scans each, were acquired as follows: DWI-MR using parallel imaging SENSE p-reduction 3; high angular gradient set of 30 different weighted directions, TR/TE = 7035/68 ms, 2 × 2 × 2 mm voxel size, 75 slices, b = 1000 s/mm, second set with reversed k-space read-out.

MR-Si examinations were conducted with 2D single-shot fast spin-echo (SSFSE) sequence (TR/TE/NSA: 8000/800/5, matrix: 192 × 256, FOV: 110 × 110 mm, bandwidth: 32 kHz, TSE factor 54, spectral presaturation with inversion recovery (SPIR), and examination period: 2 min 20 sec) with parallel imaging (SENSE) by using surface coil (synergy flex M) placed on the submandibular gland.

A DWI set of 32 weighted diffusion scans (b = 800 s/mm) and an unweighted B0 scan (b = 0 s/mm) were acquired (DWI-MR using parallel imaging SENSE P-reduction 2; TR = 5764 ms, TE = 70 ms, FOV 180 × 146.25 mm, voxel size 1.4 × 14 × 2.0 mm, 50 slices).

Two DWI sets of 30 weighted diffusion scans (b = 1000 s/mm) and 5 × 2 unweighted B0 scans (b = 0 s/mm) were acquired (DWI-MR using parallel imaging SENSE p-reduction 3; high angular gradient set of 30 weighting directions [ Jones 2008], TR = 7035 ms, TE = 68 ms, EPI factor 35; FOV 240 × 240 mm, 2 mm isotropic, 75 slices).

A separate Learn section, with interactive graphics, explains underlying principles of mechanics, electromagnetism, power generation, imaging sensing, image processing and optics.

An inexpensive CCD camera was used as a detector for imaging sensing.

These materials have found noteworthy applications in imaging, sensing, drug delivery and gene targeting.

The proposed metamaterial offers an approach in the manipulation of the light polarization and has potential applications in imaging, sensing and communications.

While all the above media have specific domains of application, hyperbolic metamaterials are a multi-functional platform to realize waveguiding, imaging, sensing, quantum and thermal engineering beyond conventional devices [13 18].