Color grading is the process of altering
and enhancing the color of a motion picture, video image, or still image
electronically, photo-chemically or digitally. Color grading encompasses both
color correction and the generation of artistic color effects. Whether for
theatrical film, video distribution, or print, color grading is generally now
performed digitally in a color suite. The earlier photo-chemical film process,
known as color timing, was performed at a photographic laboratory.
Color timing
The earliest film grading technique, known
as colour timing, involved changing the duration of exposure processes during
the film development process. Colour timing was largely used for colour
correction, but could also be used for artistic purposes. Colour timing was
specified in printer points. Since it could not be performed in real time,
colour timing for film processing involved considerable skill in being able to
predict correct exposures. For complex work, "wedges" were sometimes
processed to aid the choice of the correct grading.
Telecine
With the advent of television, broadcasters
quickly realised the limitations of live television broadcasts and they turned
to broadcasting feature films from release prints directly from a telecine.
This was before 1956 when Ampex introduced the first Quadruplex videotape
recorder (VTR) VRX-1000. Live television shows could also be recorded to film
and aired at different times in different time zones by filming a video
monitor. The heart of this system was the kinescope, a device for recording a
television broadcast to film.
The early telecine hardware was the
"film chain" for broadcasting from film and utilsed a film projector
connected to a video camera. As explained by Jay Holben in American
Cinematographer Magazine, "The telecine didn't truly become a viable
post-production tool until it was given the ability to perform colour
correction on a video signal."
Today, telecine is synonymous with colour
timing as tools and technologies have advanced to make color timing (colour
correction) ubiquitous in a video environment.
How telecine colouring works
In a Cathode-ray tube (CRT) system, an
electron beam is projected at a phosphor-coated envelope, producing a spot of
light the size of a single pixel. This beam is then scanned across a film frame
from left to right, capturing the "vertical" frame information.
Horizontal scanning of the frame is then accomplished as the film moves past
the CRT's beam. Once this photon beam passes through the film frame, it
encounters a series of dichroic mirrors which separate the image into its
primary red, green and blue components. From there, each individual beam is
reflected onto a photomultiplier tube (PMT) where the photons are converted
into an electronic signal to be recorded to tape.
In a charge-coupled device (CCD) telecine,
a white light is shone through the exposed film image onto a prism, which
separates the image into the three primary colors, red, green and blue. Each
beam of colored light is then projected at a different CCD, one for each color.
The CCD converts the light into an electronic signal, and the telecine
electronics modulate these into a video signal that can then be color graded.
Early color correction on Rank Cintel MkIII
CRT telecine systems was accomplished by varying the primary gain voltages on
each of the three photomultiplier tubes to vary the output of red, green and
blue. Further advancements converted much of the color-processing equipment
from analog to digital and then, with the next-generation telecine, the Ursa,
the coloring process was completely digital in the 4:2:2 color space. The Ursa
Gold brought about color grading in the full 4:4:4 color space.
Color correction control systems started
with the Rank Cintel TOPSY (Telecine Operations Programming SYstem) in 1978. In
1984 Da Vinci Systems introduced their first color corrector, a
computer-controlled interface that would manipulate the color voltages on the
Rank Cintel MkIII systems. Since then, technology has improved to give
extraordinary power to the digital colorist. Today there are many companies
making color correction control interfaces including Da Vinci Systems, Pandora
International, Pogle and more.
Some of the main functions of electronic
(digital) color grading:
Reproduce accurately what was shot
Compensate for variations in the material
(i.e., film errors, white balance, varying lighting conditions)
Optimize transfer for use of special
effects
Establish a desired 'look'
Enhance and/or alter the mood of a scene —
the visual equivalent to the musical accompaniment of a film; compare also film
tinting
Note that some of these functions are
contrary to others; for example, color grading is often done to ensure that the
recorded colors match those of the set design, whereas in music videos, the
goal may instead be to establish a stylized look.
Traditionally, color grading was done
towards technical goals. For example, in the film Marianne, grading was used so
that night scenes could be filmed more cheaply in daylight. Secondary color correction
was originally used to establish color continuity, however the trend today is
increasingly moving towards creative goals, such as improving the aesthetics of
an image, establishing stylized looks, and setting the mood of a scene through
color. Due to this trend, some colorists suggest the phrase "color
enhancement" over "color correction".
Primary and secondary color grading
Primary color grading affects the whole
image by providing control over the color density curves of red, green, blue
color channels, across the entire frame. Secondary correction can isolate a
range of hue, saturation and brightness values to bring about alterations in
hue, saturation and luminance only in that range, allowing the grading of
secondary colors, while having a minimal or usually no effect on the remainder
of the color spectrum. Using digital grading, objects and color ranges within a
scene can be isolated with precision and adjusted. Color tints can be
manipulated and visual treatments pushed to extremes not physically possible
with laboratory processing. With these advancements, the color correction
process has become increasingly similar to well-established digital painting
techniques, ushering forth a new era of digital cinematography.
Masks, mattes, power windows
The evolution of digital color grading
tools has advanced to the point where the colorist can use geometric shapes
(such as mattes or masks in photo software such as Adobe Photoshop) to isolate
color adjustments to specific areas of an image. These tools can highlight a
wall in the background and color only that wall, leaving the rest of the frame
alone, or color everything but that wall. Subsequent color correctors
(typically software-based) have the ability to use spline-based shapes for even
greater control over isolating color adjustments. Color keying is also used for
isolating areas to adjust.
Inside and outside of area-based
isolations, digital filtration can be applied to soften, sharpen or mimic the
effects of traditional glass photographic filters in nearly infinite degrees.
Motion tracking
When trying to isolate a color adjustment
on a moving subject, the colorist traditionally would have needed to manually
move a mask to follow the subject. In its most simple form, motion tracking
software automates this time-consuming process using algorithms to evaluate the
motion of a group of pixels. These techniques are generally derived from match
moving techniques used in special effects and compositing work.
Digital intermediate
Main article: Digital intermediate
The evolution of the telecine device into
film scanning allowed the digital information gathered from a film negative to
be of sufficient resolution to transfer back to film. In the late 1990s, the
films Pleasantville and O Brother, Where Art Thou? advanced the technology to
the point that the creation of a digital intermediate was possible, which
greatly expanded the capabilities of the digital telecine colorist in a
traditionally film-oriented world. Today, many feature films go through the DI
process, while manipulation through photochemical processing is decreasing in
use.
In Hollywood
Modern motion picture processing typically
uses both digital cameras and digital projectors; when done correctly, color
correction in such a system is a technical function involving the calibration
of the different elements of the system, leaving the color grading process
entirely to the creation of artistic color effects.
Hardware-based versus software-based
systems
Hardware-based systems (da Vinci 2K,
Pandora International MegaDEF, etc.) have historically offered better
performance and a smaller feature set than software-based systems. Their real
time performance was optimised to particular resolution and bit depths, as
opposed to software platforms using standard computer industry hardware that
often trade speed for resolution independence, e.g. Apple's Color (previously
Silicon Color Final Touch), ASSIMILATE SCRATCH, Adobe SpeedGrade and SGO
Mistika. While hardware-based systems always offer real-time performance, some
software-based systems need to render as the complexity of the color grading increases.
On the other hand, software-based systems tend to have more features such as
spline-based windows/masks and advanced motion tracking.
The line between hardware and software is
blurring as many software-based color correctors (e.g. Pablo , Mistika,
SCRATCH, Autodesk Lustre, Nucoda Film Master and Filmlight Baselight) use multi
processor workstations and a GPU (graphics processing unit) as a means of
hardware acceleration. As well, some newer software-based systems use a cluster
of multiple parallel GPUs on the one computer system to improve performance at
the very high resolutions required for feature film grading. e.g. Blackmagic
Designs' DaVinci Resolve. Some color grading software like Synthetic Aperture's
Color Finesse runs solely as software and will even run on low-end computer
systems.
Hardware
"Pogle" redirects here. For other
uses, see Pogle (disambiguation).
The control panels are placed in a color
suite for the colorist to operate.
For high-end systems many telecines are
controlled by a Da Vinci Systems color corrector 2k or 2k Plus, which is also
called color grading.
Other high-end systems are controlled by
Pandora Int.'s Pogle, often with either a MegaDEF, Pixi, or Revolution color
grading system.
Additionally, color grading systems require
an edit controller. The edit controller controls the telecine and a VTR(s) or
other recording/playback devices to ensure frame accurate film frame editing.
There are a number of systems which can be used for edit control. Some color grading
products such as Pandora Int.'s Pogle have a built in edit controller.
Otherwise, a separate device such as Da Vinci Systems' TLC edit controller
would be used.
Older systems are: Renaissance, Classic
analog, Da Vinci Systems's: The Whiz (1982) and 888; The Corporate
Communications's System 60XL (1982–1989) and Copernicus-Sunburst; Bosch
Fernseh's FRP-60 (1983–1989); Dubner (1978–1985?), Cintel's TOPSY (1978), Amigo
(1983), and ARCAS (1992) systems. All of these older systems work only with
standard-definition 525 and 625 video signals, and are considered near obsolete
today.
Software
The controls are shown on-screen and are
sometimes accessed as a plugin to a host application.
Baselight from FilmLight is used for HD,
2K, 4K and 3D color grading. Grade operations are controlled via Blackboard.
Program supports variety of film and video formats and codecs. FilmLight
systems utilises cluster and cloud technology in Linux environment.
Nucoda from Digital Vision provides advance
color grading tools working with ACES and HDR at SD to 8K as well as industry
leading restoration and image enhancement tools.
Software like Synthetic Aperture's Color
Finesse runs as a plugin in host applications like Apple's Final Cut Pro,
Adobe's After Effects and Premiere.
Da Vinci Systems from Blackmagic Design
operates on Mac OS X, Windows 7 Pro and Linux OS utilizing a cluster of
multiple parallel GPUs for real time grading of HD, 2K and 4K images in 2D or
Stereoscopic 3D.
SpeedGrade from Adobe Systems released as a
part of Creative Suite 6 and Creative Cloud works on Mac and PC. It works on
layers interface and the workflow is linked to Premiere Pro and After Effects.
Magic Bullet Colorista II from Red Giant
Software offers multi-step color correction with primary, secondary and master
stages inside host applications including Apple's Final Cut Pro, Adobe's After
Effects and Premiere.
The Grading Sweet is a package of
specialized Color Grading plugins for Apple's Final Cut Pro.
Sony Vegas has many built-in filters as
well as third-party plugins for color grading.
Apple Final Cut Studio 2 contains Apple
Color which is a dedicated software application for color grading.
Bones Dailies by Digital Film Technology
Other programs have their own color grading
options (for example Edius or Blender).
Autodesk Lustre is a high-end color grading
solution. It features GPU acceleration for most functions.
YUVsoft Color Corrector Adobe After Effects
plug-in for Stereo3D color grading.
Mistika (SGO) is a color grading and online
editing system.
Quantel's Pablo Rio color correction and
finishing system is available as software only or in a range of turnkey
configurations.
Assimilate Scratch has advanced color
grading and compositing tools and is used for creating digital dailies and for
final finishing. It runs in Mac and Windows environments.
Film Convert is a simple color grading tool
that converts digital footage to emulate the look of real film stocks
Source From Wikipedia
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