K-space (magnetic resonance imaging) - definition. What is K-space (magnetic resonance imaging)
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%ما هو (من)٪ 1 - تعريف

Kspace; K-space (MRI)
  • For a real image, the corresponding ''k''-space is conjugate symmetric: the imaginary component at opposite ''k''-space coordinates has the opposite sign.

K-space (magnetic resonance imaging)         
In magnetic resonance imaging (MRI), k-space is the 2D or 3D Fourier transform of the image measured.
MRI         
  • A mobile MRI unit visiting Glebefields Health Centre, [[Tipton]], England
  • Motion artifact (T1 coronal study of cervical vertebrae)<ref name="ErasmusHurter2004"/>
  • Schematic of construction of a cylindrical superconducting MR scanner
  • MR angiogram in congenital heart disease
  • Real-time MRI of a [[human heart]] at a resolution of 50&nbsp;ms
  • Patient being positioned for MR study of the head and abdomen
  • PD-weighted]] MRI scans
  • Effects of TR and TE on MR signal
  • MRI diffusion tensor imaging of [[white matter]] tracts
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MRI; Magnetic Resonance Imaging; MRI scan; 1H-nuclear magnetic resonance spectroscopic imaging; NMR imaging; Magnetic resonance tomography; MRIs; MRI body scanner; MRI's; T2 (MRI); Contrast MRI; Mri; Zeugmatography; Mri scan; Nuclear scanning; Magnetic resonance image; MRI Scanner; MRI exam; Nuclear magnetic resonance imaging; Unsolved problems in diagnostic imaging; Open MRI; Magnetic Resonance Image; MRI scans; MRI-screen; Nuclear Magnetic Resonance Imaging; Magnetic resonance Imaging; EU Physical Agents (Electromagnetic Fields) Directive; T2 MRI; T2 weighted imaging; T2-weighted imaging; T2-weighted MRI; MRI machine; Magnetic resonance topography; MR scanning; Magnetic Resonance Tomography; T2*-weighted; Magnetic resonance urography; Magnetice resonance imaging; 3 Tesla MRI; 3-Tesla MRI; 3T MRI; 3 T MRI; 3-T MRI; Magnetic resonance images; Magnetic-resonance imaging; Proton density MRI; Spectral presaturation with inversion recovery; T2 weighted; Clinical MRI; Clinical NMRI; Clinical magnetic resonance imaging; T1-weighted; T2-weighted; Magnet resonance imaging
MRI         
  • A mobile MRI unit visiting Glebefields Health Centre, [[Tipton]], England
  • Motion artifact (T1 coronal study of cervical vertebrae)<ref name="ErasmusHurter2004"/>
  • Schematic of construction of a cylindrical superconducting MR scanner
  • MR angiogram in congenital heart disease
  • Real-time MRI of a [[human heart]] at a resolution of 50&nbsp;ms
  • Patient being positioned for MR study of the head and abdomen
  • PD-weighted]] MRI scans
  • Effects of TR and TE on MR signal
  • MRI diffusion tensor imaging of [[white matter]] tracts
NON-DESTRUCTIVE TECHNIQUE FOR IMAGING INTERNAL STRUCTURES OF OBJECTS OR ORGANISMS
MRI; Magnetic Resonance Imaging; MRI scan; 1H-nuclear magnetic resonance spectroscopic imaging; NMR imaging; Magnetic resonance tomography; MRIs; MRI body scanner; MRI's; T2 (MRI); Contrast MRI; Mri; Zeugmatography; Mri scan; Nuclear scanning; Magnetic resonance image; MRI Scanner; MRI exam; Nuclear magnetic resonance imaging; Unsolved problems in diagnostic imaging; Open MRI; Magnetic Resonance Image; MRI scans; MRI-screen; Nuclear Magnetic Resonance Imaging; Magnetic resonance Imaging; EU Physical Agents (Electromagnetic Fields) Directive; T2 MRI; T2 weighted imaging; T2-weighted imaging; T2-weighted MRI; MRI machine; Magnetic resonance topography; MR scanning; Magnetic Resonance Tomography; T2*-weighted; Magnetic resonance urography; Magnetice resonance imaging; 3 Tesla MRI; 3-Tesla MRI; 3T MRI; 3 T MRI; 3-T MRI; Magnetic resonance images; Magnetic-resonance imaging; Proton density MRI; Spectral presaturation with inversion recovery; T2 weighted; Clinical MRI; Clinical NMRI; Clinical magnetic resonance imaging; T1-weighted; T2-weighted; Magnet resonance imaging
MRI is a method by which medical staff can get a picture of soft parts inside a patient's body, using a powerful magnetic field. MRI is an abbreviation for 'magnetic resonance imaging'.
N-UNCOUNT

ويكيبيديا

K-space (magnetic resonance imaging)

In magnetic resonance imaging (MRI), k-space is the 2D or 3D Fourier transform of the image measured. It was introduced in 1979 by Likes and in 1983 by Ljunggren and Twieg.

In MRI physics, complex values are sampled in k-space during an MR measurement in a premeditated scheme controlled by a pulse sequence, i.e. an accurately timed sequence of radiofrequency and gradient pulses. In practice, k-space often refers to the temporary image space, usually a matrix, in which data from digitized MR signals are stored during data acquisition. When k-space is full (at the end of the scan) the data are mathematically processed to produce a final image. Thus k-space holds raw data before reconstruction.

The concept of k-space is situated in the spatial frequency domain. Thus if we define k F E {\displaystyle k_{\mathrm {FE} }} and k P E {\displaystyle k_{\mathrm {PE} }} such that

k F E = γ ¯ G F E m Δ t {\displaystyle k_{\mathrm {FE} }={\bar {\gamma }}G_{\mathrm {FE} }m\Delta t}

and

k P E = γ ¯ n Δ G P E τ {\displaystyle k_{\mathrm {PE} }={\bar {\gamma }}n\Delta G_{\mathrm {PE} }\tau }

where FE refers to frequency encoding, PE to phase encoding, Δ t {\displaystyle \Delta t} is the sampling time (the reciprocal of sampling frequency), τ {\displaystyle \tau } is the duration of GPE, γ ¯ {\displaystyle {\bar {\gamma }}} (gamma bar) is the gyromagnetic ratio, m is the sample number in the FE direction and n is the sample number in the PE direction (also known as partition number), then the 2D-Fourier Transform of this encoded signal results in a representation of the spin density distribution in two dimensions. Thus position (x,y) and spatial frequency ( k F E {\displaystyle k_{\mathrm {FE} }} , k P E {\displaystyle k_{\mathrm {PE} }} ) constitute a Fourier transform pair.

Typically, k-space has the same number of rows and columns as the final image and is filled with raw data during the scan, usually one line per TR (Repetition Time).

An MR image is a complex-valued map of the spatial distribution of the transverse magnetization Mxy in the sample at a specific time point after an excitation. Conventional qualitative interpretation of Fourier Analysis asserts that low spatial frequencies (near the center of k-space) contain the signal to noise and contrast information of the image, whereas high spatial frequencies (outer peripheral regions of k-space) contain the information determining the image resolution. This is the basis for advanced scanning techniques, such as the keyhole acquisition, in which a first complete k-space is acquired, and subsequent scans are performed for acquiring just the central part of the k-space; in this way, different contrast images can be acquired without the need of running full scans.

A nice symmetry property exists in k-space if the image magnetization Mxy is prepared to be proportional simply to a contrast-weighted proton density and thus is a real quantity. In such a case, the signal at two opposite locations in k-space is:

S ( k F E , k P E ) = S ( k F E , k P E ) {\displaystyle S(-k_{\mathrm {FE} },-k_{\mathrm {PE} })=S^{*}(k_{\mathrm {FE} },k_{\mathrm {PE} })\,}

where the star ( {\displaystyle ^{*}} ) denotes complex conjugation. Thus k-space information is somewhat redundant then, and an image can be reconstructed using only one half of the k-space, either in the PE (Phase Encode) direction saving scan time (such a technique is known as half Fourier or half scan) or in the FE (Frequency Encode) direction, allowing for lower sampling frequencies and/or shorter echo times (such a technique is known as half echo). However, these techniques are approximate due to phase errors in the MRI data which can rarely be completely controlled (due to imperfect static field shim, effects of spatially selective excitation, signal detection coil properties, motion etc.) or nonzero phase due to just physical reasons (such as the different chemical shift of fat and water in gradient echo techniques).

MRI k-space is related to NMR time-domain in all aspects, both being used for raw data storage. The only difference between the MRI k-space and the NMR time domain is that a gradient G is present in MRI data acquisition, but is absent in NMR data acquisition. As a result of this difference, the NMR FID signal and the MRI spin-echo signal take different mathematical forms:

FID = M 0 {\displaystyle {\text{FID}}=M_{\mathrm {0} }} cos ( ω 0 t ) {\displaystyle (\omega _{\mathrm {0} }t)} exp ( t / T 2 ) {\displaystyle (-t/T_{\mathrm {2} })}

and

Spin-Echo = M 0 {\displaystyle {\text{Spin-Echo}}=M_{\mathrm {0} }} sin ( ω r t ) / ( ω r t ) {\displaystyle (\omega _{\mathrm {r} }t)/(\omega _{\mathrm {r} }t)}

where

ω r = ω 0 + γ ¯ r G {\displaystyle \omega _{\mathrm {r} }=\omega _{\mathrm {0} }+{\bar {\gamma }}rG}

Due to the presence of the gradient G, the spatial information r (not the spatial frequency information k) is encoded onto the frequency ω {\displaystyle \omega } , and at the same time the time-domain is renamed as k-space.