Question

Describe the locations of the Fresnel and Fraunhofer zones

Discuss the other names by which axial and lateral resolution may be referred to

Answer 1

Fraunhofer diffraction, or far-field diffraction, is a form of wave diffraction that occurs when field waves are passed through an aperture or slit causing only the size of an observed aperture image to change due to the far-field location of observation and the increasingly planar nature of outgoing diffracted waves passing through the aperture. It is observed at distances beyond the near-field distance of Fresnel diffraction, which affects both the size and shape of the observed aperture image, and occurs only when the Fresnel number F<<1, wherein the parallel rays approximation can be applied.

On the other hand, Fresnel diffraction or near-field diffraction is a process of diffraction that occurs when a wave passes through an aperture and diffracts in the near field, causing any diffraction pattern observed to differ in size and shape, depending on the distance between the aperture and the projection. It occurs due to the short distance in which the diffracted waves propagate, which results in a Fresnel number greater than 1 (F>1). When the distance is increased, outgoing diffracted waves become planar and Fraunhofer diffraction occurs

*Axial resolution, also known as longitudinal, depth or linear resolution resolution is resolution in the direction parallel to the ultrasound beam. The resolution at any point along the beam is the same; therefore axial resolution is not affected by depth of imaging.

* Lateral resolution:it is also known as azimuthal resolution thit asis edefined as ability of the system to distinguish two points in the direction perpendicular to the direction of the ultrasound beam. Lateral resolution is affected by the width of the beam and the depth of imaging. Wider beams typically diverge further in the far field and any ultrasound beam diverges at greater depth, decreasing lateral resolution. Therefore, lateral resolution is best at shallow depths and worse with deeper imaging.