transfer line technique - translation to russian
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transfer line technique - translation to russian

FUNCTION THAT SPECIFIES HOW DIFFERENT SPATIAL FREQUENCIES ARE HANDLED BY THE SYSTEM; DESCRIBES HOW THE OPTICS PROJECT LIGHT FROM THE OBJECT OR SCENE ONTO A PHOTOGRAPHIC FILM, DETECTOR ARRAY, RETINA, SCREEN, ETC.
Modulation Transfer Function; Modulation transfer function; Phase Transfer Function; Optical Transfer Function; Modulation transfer function (infrared imaging); MTF chart; Phase transfer function; Line spread function
  • The three-dimensional point spread functions (a,c) and corresponding modulation transfer functions (b,d) of a wide-field microscope (a,b) and confocal microscope (c,d). In both cases the numerical aperture of the objective is 1.49 and the refractive index of the medium 1.52. The wavelength of the emitted light is assumed to be 600 nm and, in case of the confocal microscope, that of the excitation light 500 nm with circular polarization. A section is cut to visualize the internal intensity distribution. The colors as shown on the logarithmic color scale indicate the irradiance (a,c) and spectral density (b,d) normalized to the maximum value.
  • Various closely related characterizations of an optical system exhibiting coma, a typical aberration that occurs off-axis. (a) The point-spread function (PSF) is the image of a point source. (b) The image of a line is referred to as the line-spread function, in this case a vertical line. The line-spread function is directly proportional to the vertical integration of the point-spread image. The optical-transfer function (OTF) is defined as the Fourier transform of the point-spread function and is thus generally a two-dimensional complex function. Typically only a one-dimensional slice is shown (c), corresponding to the Fourier transform of the line-spread function. The thick green line indicates the real part of the function, and the thin red line the imaginary part. Often only the absolute value of the complex function is shown, this allows visualization of the two-dimensional function (d); however, more commonly only the one-dimensional function is shown (e). The latter is typically normalized at the spatial frequency zero and referred to as the modulation transfer function (MTF). For completeness, the complex argument is sometimes provided as the phase transfer function (PhTF), shown in panel (f).
  • Illustration of the optical transfer function (OTF) and its relation to image quality. The optical transfer function of a well-focused (a), and an out-of-focus optical imaging system without aberrations (d). As the optical transfer function of these systems is real and non-negative, the optical transfer function is by definition equal to the modulation transfer function (MTF). Images of a point source and a [[spoke target]] with high [[spatial frequency]] are shown in (b,e) and (c,f), respectively. Note that the scale of the point source images (b,e) is four times smaller than the spoke target images.
  • The '''MTF''' data versus spatial frequency is normalized by fitting a sixth order polynomial to it, making a smooth curve. The 50% cut-off frequency is determined and the corresponding '''spatial frequency''' is found, yielding the approximate position of '''best focus'''.
  • date=August 2013}} of the total frame area of a '''knife-edge test target''' back-illuminated by a '''black body'''. The area is defined to encompass the edge of the target image.
  • When viewed through an optical system with trefoil aberration, the image of a point object will look as a three-pointed star (a). As the point-spread function is not rotational symmetric, only a two-dimensional optical transfer function can describe it well (b). The height of the surface plot indicates the absolute value and the hue indicates the complex argument of the function. A spoke target imaged by such an imaging device is shown by the simulation in (c).

transfer line technique      
метод производства с использованием автоматических станочных линий
transfer fee         
  • In 1996, Dutchman [[Edgar Davids]] was the first high-profile player to move on a free transfer via the [[Bosman ruling]].
  • [[John Hartson]] failed medical tests which led to the shelving of three potential transfers in 2000.
  • Bayern Munich]] from [[RB Leipzig]] for a world record-breaking fee of €25 Million in 2021.
  • [[Neymar]] (right) and [[Kylian Mbappé]] (left) are the two most expensive association football transfers.
  • Barcelona]] in 2013 became the subject of investigation.
  • Manchester City paid Santos €1.805 million in solidarity contribution for Robinho.
  • [[Zinedine Zidane]] was the most expensive player in the world for eight years.
SPORTS ACTION IN WHICH A PLAYER MOVES BETWEEN CLUBS
Football Transfers; Transfer fee; Transfer fees; Football transfer; Transfer deal; English Football Transfers; Transfer ban (association football); Transfer (football); Solidarity Contribution (football); Player transfer; 2013 summer transfer window; Transfer embargo; Training compensation; Globalization of the football transfer market; User:Howley.l/sandbox; Impact of globalization on the football transfer market; Solidarity contribution; Association football transfer; Transfer of Neymar from Santos FC to FC Barcelona; Solidarity contributions (association football)
комиссия за трансферт
modulation transfer function         
функция передачи модуляции (фотографическим материалом)

Definition

Ватерлиния
(голл. water-lijn, от water - вода и lijn - линия)

линия соприкасания поверхности воды с корпусом плавающего судна. Грузовая В. совпадает со спокойной поверхностью воды при полной загрузке судна и соответствует наибольшей допускаемой в эксплуатации осадке; положение грузовой В. отмечается грузовой маркой (См. Грузовая марка). Теоретические В., изображаемые на теоретическом чертеже судна, получают сечением поверхности корпуса судна горизонтальными плоскостями. Форма В. и величина очерченной ею площади влияют на характеристики ходкости и остойчивости судна.

Wikipedia

Optical transfer function

The optical transfer function (OTF) of an optical system such as a camera, microscope, human eye, or projector specifies how different spatial frequencies are captured or transmitted. It is used by optical engineers to describe how the optics project light from the object or scene onto a photographic film, detector array, retina, screen, or simply the next item in the optical transmission chain. A variant, the modulation transfer function (MTF), neglects phase effects, but is equivalent to the OTF in many situations.

Either transfer function specifies the response to a periodic sine-wave pattern passing through the lens system, as a function of its spatial frequency or period, and its orientation. Formally, the OTF is defined as the Fourier transform of the point spread function (PSF, that is, the impulse response of the optics, the image of a point source). As a Fourier transform, the OTF is complex-valued; but it will be real-valued in the common case of a PSF that is symmetric about its center. The MTF is formally defined as the magnitude (absolute value) of the complex OTF.

The image on the right shows the optical transfer functions for two different optical systems in panels (a) and (d). The former corresponds to the ideal, diffraction-limited, imaging system with a circular pupil. Its transfer function decreases approximately gradually with spatial frequency until it reaches the diffraction-limit, in this case at 500 cycles per millimeter or a period of 2 μm. Since periodic features as small as this period are captured by this imaging system, it could be said that its resolution is 2 μm. Panel (d) shows an optical system that is out of focus. This leads to a sharp reduction in contrast compared to the diffraction-limited imaging system. It can be seen that the contrast is zero around 250 cycles/mm, or periods of 4 μm. This explains why the images for the out-of-focus system (e,f) are more blurry than those of the diffraction-limited system (b,c). Note that although the out-of-focus system has very low contrast at spatial frequencies around 250 cycles/mm, the contrast at spatial frequencies near the diffraction limit of 500 cycles/mm is diffraction-limited. Close observation of the image in panel (f) shows that the image of the large spoke densities near the center of the spoke target is relatively sharp.

What is the Russian for transfer line technique? Translation of &#39transfer line technique&#39 to R