http://pro.sony.com/bbsccms/static/f...K_WP_Final.pdf
Introduction.
Movie theaters are on the threshold of an historic transformation from
film to digital projection. The technology is in place, with broadly
accepted specifications and a range of commercially available
equipment that supports those specifications. An economic model is
also in place, with procedures that enable distributors and exhibitors
to share the cost of the digital conversion. One major remaining
question is the choice of 2K or 4K digital projection. The choice that
theater owners make today will enableor limitthe quality and
flexibility of their presentations for years to come.
4K Projection
4096 H x 2160 V
8,847,360 pixels
2K Projection
2048 H x 1080 V
2,211,840 pixels
4K delivers precisely four times the pixels of 2K.
2K digital cinema provides an image container roughly 2000 pixels
across (2048 x 1080 or 2.2 million pixels). 4K digital cinema doubles
those dimensions to 4096 x 2160. This equals 8.8 million pixels,
exactly four times the count for 2K projection. On paper, 4K is
obviously the superior solution. But what about the real world? Will
the ticket buying public actually be able to perceive the benefits of 4K
What you see depends on where you sit.
One key to an audience member's ability to pick out detail on a movie screen is
the distance from that person to the screen, the viewing distance. You can
appreciate the role of distance by considering printed material, such as a printout
of this document.1 Most readers will have little trouble identifying individual
letters of the text at a distance of 2 feet (0.6 m). At 20 feet (6 m), you'd be doing
well to discern the largest headlines. At 200 feet (60 m), you can only see that it
is a sheet of paper. At 2000 feet (600 m), you can't even see that.
This suggests that for some sufficiently large viewing distance, high definition TV
looks no sharper than standard definition. And for some other sufficiently large
viewing distance, 4K digital cinema projection will appear no sharper than 2K.
But there's a flip side. For audience members who sit close enough to the
screen, 2K projection will have visible limitations.
Any comparison between 2K and 4K projection must address three important
questions. What is the acuity of human vision? What are the viewing distances
in actual, real-world theaters? And how do those distances compare with the
distance at which the issues in 2K projection become visible?
What you see depends on your visual acuity.
You can change screen sizes. You can change viewing distances. You can
change the number of pixels projected. But one thing you cannot change is the
visual acuity of the audience. The consensus standard for good vision is a
Snellen fraction of 20/20, which is referenced to feet. (Outside the United States,
this would be 6/6, referenced to meters.)
5'
1'
1'
1'
1'
1'
A single degree of viewing angle is equal to 60 subdivisions called
"arcminutes." Seen from a distance of 20 feet, the letter E on the 20/20
line of an eye chart is just five arcminutes high. Each stroke of the letter
(and each void between strokes) is one arcminute wide.
But what does 20/20 vision actually mean? It means that the observer at 20 feet
can discern letters down to the 20/20 line of an eye chart. These letters are
sized to occupy a small fraction of one degree of viewing angle. One degree is
equal to sixty subdivisions called "arcminutes." The letters are five arcminutes in
height, meaning that 12 of these letters stacked one on top of the other would
occupy just one degree of viewing angle. The strokes and voids that form the
letters are one arcminute thick.2 For viewers with 20/20 vision, the smallest
observable detail is one arcminute.3
One arcminute of visual acuity means that human observers can discern 60
digital pixels per degree. This is also called 30 dark-to-light cycles per degree or
30 line pairs per degree. This reference for visual acuity has been used by
motion imaging engineers for decades.4
Some argue that this reference is too conservative. For example, researchers at
NHK, the Japanese national broadcaster have reported that viewers can
distinguish between pictures that present 156 and 78 cycles per degree. This
equates to 312 and 156 pixels per degree respectivelyacuity far greater than
20/20 vision would imply.5 Certainly many audience members have better than
normal vision, 20/10 for example.
Others take the opposite approach and recommend a more relaxed reference
that corresponds to detail that humans can "clearly" see: 1.03 arcminutes,6 which
equal 58 pixels per degree. Still others have proposed a far more relaxed
reference: 44 pixels per degree, said to be the level of detail that humans can
"reliably" see.7 This, the most relaxed reference of all, is the friendliest to 2K
digital cinema projection and the least favorable to 4K. Nevertheless, we will
make the argument for 4K using this most conservative reference, 44 pixels per
degree, as well as the widely accepted standard of 60 pixels per degree.
Needless to say, this discussion of acuity holds true for objects that are
sufficiently bright and have sufficiently high contrast. For projected images, it
requires that the projectors actually be in focus. It also assumes that the viewer
is looking directly at the object, using the "fovea" of the eye, the visual center of
the retina where acuity is highest. A more complete analysis might involve
screen brightness, viewer contrast sensitivity and angles of eccentricity from the
fovea.
Picture Height: the measure of viewing distance.
When the standard definition television system was first launched in North
America, engineers assumed that viewers would want to sit at a sufficient
distance for the individual scanning lines that comprise the picture to blend into a
visually seamless whole. In the days before pixels, these engineers figured on
60 horizontal scanning lines per degree. From this, they derived a standard
viewing distance of 7.15 Picture Heights (PH).
Studies by Bernard Lechner of RCA in the US and Richard Jackson at Philips
Laboratories in Europe determined that actual viewing distance for standard
definition TV is around 10 feet (3 meters).8 The screen size that corresponds to
7.15 Picture Heights at this distance is 28 inches diagonal. This roughly matches
the larger CRT sizes of the standard definition era.
Movie theater design has been influenced by similar calculations. In the 1940s,
the Society of Motion-Picture Engineers (SMPE) made a recommendation called
the 2-6 rule.9 It proposed that theater auditoriums be designed with the nearest
seats at two times picture width and the farthest at six times picture width. Using
the Academy Aperture screen shape of the time, that translates to a minimum
viewing distance of 2.67 Picture Heights.
When high definition television was first proposed, the design goal was to equal
the performance of movie theaters. This dictated an increase in TV resolution
sufficient to create the illusion of a seamless image at roughly three Picture
Heights.10 (The actual figure is 3.16 Picture Heights.) This similarity to the 2.67
specification of old movie theaters is not a coincidence. It is by design.
Since the 1940s, just about everything in movie theaters has been transformed,
including auditorium design. Through the 1990s, new theater designs moved to
progressively wider-angle projection lenses, which suggests that seats became
progressively closer to the screen.11 Today in many stadium seating auditoriums,
the back of the room is three Picture Heights, a distance formerly among the
closest seats in the house. The closest seats are less than one Picture Height
from the screen.
1
Viewing distance and viewing angle.
Any specified viewing distance also enables us to calculate the angle of view that
the picture occupies. In the sample 298-seat auditorium, the front row is roughly
one Picture Height from the screen while the back row is roughly three Picture
Heights. The most desired seats for the most enthusiastic ticket holders are
roughly 1.5 Picture Heights from the screen. At this distance, the vertical angle
of view is 37°.
How many pixels does a viewer require?
We can multiply this vertical angle of view by the number of pixels per degree to
determine the number of vertical pixels required to produce a visibly seamless
image for a viewer with good eyesight. The "relaxed" reference of 44 pixels per
degree multiplied by 37 degrees vertical equals 1628 pixels vertical.
How does this number compare to 2K? The typical modern movie has a picture
width-to-height proportion ("aspect ratio") of 1.85:1. 2K projection
accommodates this aspect ratio picture with 1998 pixels horizontal by 1080
pixels vertical. (Different aspect ratios use different accommodations.12) The
1080 pixels of 2K projection fall 34% short of the 1628 pixels required to create a
seamless picture.
Of course, this 2K shortfall varies according to viewing distance. Sit closer and
the shortfall becomes more severe. Sit further and the shortfall will diminish,
eventually to zero. The shortfall is also linked to the reference for visual acuity.
Using 60 pixels per degree, which corresponds to recognizing the "E" on the
20/20 line of the eye chart, 2K projection can only provide half of the required
2220 pixels.13
Assuming appropriate content and a 2K projector that's in focus, the 2K shortfall
can create a problem for viewers in contemporary stadium seating theaters. At
practical viewing distances, the drawbacks of 2K presentation will be visible.
These limitations can include the visibility of individual pixels, which can
undermine the illusion of reality. Stairstep "jaggies" can add unwanted texture to
diagonal lines in the picture. And gaps between pixels can put a fine mesh of
black lines across the entire image, as if the picture were viewed through a
screen door. (And if a projectionist were to deliberately put a 2K projector out of
focus to conceal these artifacts, the picture would lose even more detail.) For
many audience members, the benefits of 4K projection will be visible.
This exaggerated view depicts the effect of stairstep "jaggies" and screen
door effect that become visible when you're sitting sufficiently close to a
digital projection.
Threshold of visibility for 2K pixels.
Even though the limitations of 2K are visible from a distance of 1.5 Picture
Heights, there still must be some distance at which 2K projection "satisfies"
viewers by providing a visibly seamless picture. At this threshold distance, 4K no
longer delivers an advantage. At the relaxed reference of 44 pixels per degree,
the threshold distance is 2.30 times the Picture Height. Viewers sitting closer
than 2.30 Picture Heights can see a benefit to 4K. Viewers sitting farther than
2.30 Picture Heights will see no benefit. If you pace off 2.30 Picture Heights in
the sample 298-seat auditorium, you'll find that audience members in only the
last four out of 13 rows are at a distance potentially satisfied by 2K projection.
Ticket holders in all the other rows, representing 69% of the audience, will not be
satisfied by 2K.
Possibly
satisfied
by 2K
Not satisfied by 2K
2.30 PH
Using the relaxed reference of 44 pixels per degree, 2K projection falls
short for 69% of audience members in this auditorium.
Here again, our conclusion is inextricably linked to the reference for visual acuity.
If we use the more stringent reference of 60 pixels per degreethe standard
invoked for decades in the design of motion imaging systemsthen 2K fares
considerably worse. The distance at which the 4K advantage can no longer be
seen increases to 3.16 Picture Heights. (This is the same threshold distance as
HDTV, which provides the same 1080 vertical pixels as 2K.) In the theater, this
is beyond the back wall of the auditorium. Using this reference, 100% of
audience members with good vision will be dissatisfied by 2K.
Not satisfied by 2K
3.16 PH
Using the more stringent reference of 60 pixels per degree, no audience
members will be satisfied by 2K projection.
Similar results apply to a smaller, 104-seat stadium seating auditorium.
Seeing the 4K difference for yourself.
It is possible to simulate the difference between 2K and 4K projection. The
following page provides side-by-side images14 for your evaluation. View a color
printout of this page from 8 feet, 7 inches (2.6 meters) to simulate first row seats
at 0.86 Picture Heights. From close viewing, you can easily see the difference
between the two images, especially in the windows and archways. As you would
expect, the further back you move, the less distinct the differences become.
To Simulate View from
(feet)
View from
(meters)
Digital cinema from 0.86 Picture Heights 8 feet 7 inches 2.6 meters
Digital cinema from 1.0 Picture Height 10 feet 3.0 meters
Digital cinema from 2.0 Picture Heights 20 feet 6.0 meters
Digital cinema from 3.0 Picture Heights 30 feet 9.0 meters
Of course, this demonstration is only a rough approximation of what happens in a
darkened theater.
4K projection and the 4K content pipeline.
Where are the 4K movies? As of August 2008, no digital cinematography system
can fully exploit the advantages of 4K projection. In the short run, the 4K
difference is most clearly evident with still images. However 4K content is
coming soon.
For example, digital cameras designated "4K" have already been used to shoot
features including Steven Soderbergh's "Che" (Red One camera) and Levar
Burton's "Reach for Me" (Dalsa Origin camera). While these cameras achieve
higher than HD resolution, at least one of their manufacturers has acknowledged
that their camera uses a Bayer color filter and actually achieves less than 4K
resolutioncloser to 3K. Several camera companies are now racing to introduce
the first digital cinema cameras to attain true 4K resolution.
The recent history of digital cinema leads us to expect true 4K movies soon.
After all, digital cinema production technology gets more sophisticated every day.
Before "Star Wars: Episode II, Attack of the Clones," digital cinematography was
an unproven concept. Today it is commonplace. Before "O Brother, Where Art
Thou?" the Digital Intermediate (DI) was unknown. Today the DI is standard
practice. And in just a few short years, digital cinematography has made heroic
strides in resolution, color and contrast handling. Given the unceasing progress
of digital technology, it is inevitable that true 4K productions will become common
early in the operating life of 2K digital cinema projectors.
At the studios, both Sony Pictures Entertainment and Warner Brothers have
been vocal in their support of 4K distribution. To see what studio executives are
saying about 4K, please download the newsletter at
http://pro.sony.com/bbsccms/assets/f...er/4K_DCinema_
5.pdf.
Toward more immersive entertainment.
Until the 1950s, cinema was overwhelmingly in black-and-white, with
monophonic sound and the squarish 1.333:1 aspect ratio. The advent of
television forced the cinema to adopt more immersive modes of presentation,
including color, widescreen "scope" pictures, stereo sound, and eventually digital
surround sound.
One by one, each of these cinema advances has been matched by home
entertainment. Television adopted color (starting in the 1950s), stereo sound
(1980s), widescreen presentation and digital surround sound (1990s). Today,
increasingly affordable 1080p high definition televisions challenge the cinema
with resolution that is in some ways comparable to 35mm film and is almost
exactly equal to 2K resolution. With 1.85 aspect ratio content, 2K has exactly the
same number of vertical pixels as HDTV, and just 4.1% more horizontal pixels.
Simply stated, 2K is insufficient to position the cinema as clearly superior to
HDTV. Visible pixels, jagged outlines and screen door effect won't work when
your audiences can enjoy superb pictures of nearly identical resolution at home.
And whatever value 2K may have in the short term, it will certainly be undercut
as the studios increasingly roll out 4K distribution. Investment in 2K digital
cinema projection is in effect a bet against the relentless advance of digital
technology.
1080p Home HDTV
1920 H x 1080 V
2,073,600 pixels
2K Projection
1.85 Aspect Ratio
1998 H x 1080 V
2,157,840 pixels
When projecting 1.85 aspect ratio content, 2K projection provides only
4.1% more pixels than HDTV showing 1.78 aspect ratio content.
Like color, widescreen, stereo and surround sound before it, 4K is another giant
advantage in the ongoing competition between the theater experience and
electronic entertainment in the home. 4K projection is scalable, accommodating
4K, 2K, HD and other digital content. In fact, the smaller pixels of 4K projection
and contemporary signal processing actually improve the presentation of 2K
material.15 Finally, 4K is flexible, supporting both 2D and 3D presentation. The
choice between 2K and 4K is a choice between limiting yourself with a short-term
solution and maximizing your return for years to come.
To find out more and to see 4K and 2K head-to-head in a suitable environment,
register online today at www.sony.com/digitalcinema.
Glossary.
20/20. The Snellen Fraction that represents standard visual acuity. 20/20 vision
corresponds to 60 pixels per degree and 30 line pairs per degree.
2-6 rule. A 1940s-vintage engineering recommendation for movie theaters that
specified a viewing distance of 2 to 6 times the picture width, equal to 2.67 to 8
times the picture height.
2K. A Digital Cinema distribution and projection system that uses an image
container of 2048 pixels horizontal by 1080 pixels vertical. 2K projectors can
show either 2K or 4K content.
4K. A Digital Cinema distribution and projection system that uses an image
container of 4096 pixels horizontal by 2160 pixels vertical. 4K projectors can
show either 2K or 4K content.
Arcminute. A measure of angle equal to 1/60 degree.
Aspect ratio. The ratio of picture width to picture height. In movies, this can
vary from title to title.
Aspect ratio accommodation. The method of exhibiting movies of varying
aspect ratios on a digital projector with a fixed aspect ratio. For example, while
2K projectors have 2048 x 1080 pixels, movies with an aspect ratio of 1.85 are
accommodated at 1998 x 1080 pixels.
DCI. Digital Cinema Initiatives, LLC, the body responsible for recommending
technical specifications for Digital Cinema distribution, encryption and projection.
The DCI specification supports both 2K and 4K distribution and projection.
Fovea. The visual center of the retina, where the eye is most sensitive to detail.
HDTV. High Definition Television, a family of TV broadcast and display formats
up to a maximum of 1920 pixels horizontal by 1080 pixels vertical.
Jaggies. In digital projection, stairstep effects that are especially visible at the
diagonal edges of on-screen objects. Can be annoying for audience members
sitting close to the screen.
Line pairs. Adjacent black and white lines of a given thickness, used in
resolution test charts. Visual acuity can be stated in line pairs per degree.
K. In computer-speak, two to the tenth power or 1,024. In digital film scanning,
the width of the image is described as 2K (2048) or 4K (4096) pixels.
Picture height. A measure of relative viewing distance that enables
comparison among screens of different sizes.
Pixel. Short for "picture element," the smallest independently described area of
a digital image. Pixels can be physical, as on a camera image sensor or
projector. They can also be logical, as data in a digital image file.
Screen door effect. In digital projection, a grid of black vertical and horizontal
lines between pixels that can be annoying for audience members sitting close to
the screen.
SDTV. Standard Definition Television. In the United States, this corresponds to
a digital image of 720 pixels horizontal by 480 pixels vertical.
Snellen Fraction. The eye doctor's measure of visual acuity. Standard acuity is
20/20 in the United States, referenced to feet. Internationally, it's 6/6, referenced
to meters.
Stadium seating. The modern auditorium design that pushes the audience far
closer to the screen than the classic 2-6 rule.
Viewing angle. The angle occupied by a given screen at a given viewing
location. Viewing angles increase as the audience sits closer.
Viewing distance. The distance from the screen to a given viewer. To simplify
comparisons of different screen sizes, this is often stated in terms of Picture
Height (PH).
Visual acuity. Sensitivity of the eye to detail. While most commonly stated as a
Snellen Fraction, such as 20/20, it can also be expressed in pixels per degree or
line pairs per degree.
Introduction.
Movie theaters are on the threshold of an historic transformation from
film to digital projection. The technology is in place, with broadly
accepted specifications and a range of commercially available
equipment that supports those specifications. An economic model is
also in place, with procedures that enable distributors and exhibitors
to share the cost of the digital conversion. One major remaining
question is the choice of 2K or 4K digital projection. The choice that
theater owners make today will enableor limitthe quality and
flexibility of their presentations for years to come.
4K Projection
4096 H x 2160 V
8,847,360 pixels
2K Projection
2048 H x 1080 V
2,211,840 pixels
4K delivers precisely four times the pixels of 2K.
2K digital cinema provides an image container roughly 2000 pixels
across (2048 x 1080 or 2.2 million pixels). 4K digital cinema doubles
those dimensions to 4096 x 2160. This equals 8.8 million pixels,
exactly four times the count for 2K projection. On paper, 4K is
obviously the superior solution. But what about the real world? Will
the ticket buying public actually be able to perceive the benefits of 4K
What you see depends on where you sit.
One key to an audience member's ability to pick out detail on a movie screen is
the distance from that person to the screen, the viewing distance. You can
appreciate the role of distance by considering printed material, such as a printout
of this document.1 Most readers will have little trouble identifying individual
letters of the text at a distance of 2 feet (0.6 m). At 20 feet (6 m), you'd be doing
well to discern the largest headlines. At 200 feet (60 m), you can only see that it
is a sheet of paper. At 2000 feet (600 m), you can't even see that.
This suggests that for some sufficiently large viewing distance, high definition TV
looks no sharper than standard definition. And for some other sufficiently large
viewing distance, 4K digital cinema projection will appear no sharper than 2K.
But there's a flip side. For audience members who sit close enough to the
screen, 2K projection will have visible limitations.
Any comparison between 2K and 4K projection must address three important
questions. What is the acuity of human vision? What are the viewing distances
in actual, real-world theaters? And how do those distances compare with the
distance at which the issues in 2K projection become visible?
What you see depends on your visual acuity.
You can change screen sizes. You can change viewing distances. You can
change the number of pixels projected. But one thing you cannot change is the
visual acuity of the audience. The consensus standard for good vision is a
Snellen fraction of 20/20, which is referenced to feet. (Outside the United States,
this would be 6/6, referenced to meters.)
5'
1'
1'
1'
1'
1'
A single degree of viewing angle is equal to 60 subdivisions called
"arcminutes." Seen from a distance of 20 feet, the letter E on the 20/20
line of an eye chart is just five arcminutes high. Each stroke of the letter
(and each void between strokes) is one arcminute wide.
But what does 20/20 vision actually mean? It means that the observer at 20 feet
can discern letters down to the 20/20 line of an eye chart. These letters are
sized to occupy a small fraction of one degree of viewing angle. One degree is
equal to sixty subdivisions called "arcminutes." The letters are five arcminutes in
height, meaning that 12 of these letters stacked one on top of the other would
occupy just one degree of viewing angle. The strokes and voids that form the
letters are one arcminute thick.2 For viewers with 20/20 vision, the smallest
observable detail is one arcminute.3
One arcminute of visual acuity means that human observers can discern 60
digital pixels per degree. This is also called 30 dark-to-light cycles per degree or
30 line pairs per degree. This reference for visual acuity has been used by
motion imaging engineers for decades.4
Some argue that this reference is too conservative. For example, researchers at
NHK, the Japanese national broadcaster have reported that viewers can
distinguish between pictures that present 156 and 78 cycles per degree. This
equates to 312 and 156 pixels per degree respectivelyacuity far greater than
20/20 vision would imply.5 Certainly many audience members have better than
normal vision, 20/10 for example.
Others take the opposite approach and recommend a more relaxed reference
that corresponds to detail that humans can "clearly" see: 1.03 arcminutes,6 which
equal 58 pixels per degree. Still others have proposed a far more relaxed
reference: 44 pixels per degree, said to be the level of detail that humans can
"reliably" see.7 This, the most relaxed reference of all, is the friendliest to 2K
digital cinema projection and the least favorable to 4K. Nevertheless, we will
make the argument for 4K using this most conservative reference, 44 pixels per
degree, as well as the widely accepted standard of 60 pixels per degree.
Needless to say, this discussion of acuity holds true for objects that are
sufficiently bright and have sufficiently high contrast. For projected images, it
requires that the projectors actually be in focus. It also assumes that the viewer
is looking directly at the object, using the "fovea" of the eye, the visual center of
the retina where acuity is highest. A more complete analysis might involve
screen brightness, viewer contrast sensitivity and angles of eccentricity from the
fovea.
Picture Height: the measure of viewing distance.
When the standard definition television system was first launched in North
America, engineers assumed that viewers would want to sit at a sufficient
distance for the individual scanning lines that comprise the picture to blend into a
visually seamless whole. In the days before pixels, these engineers figured on
60 horizontal scanning lines per degree. From this, they derived a standard
viewing distance of 7.15 Picture Heights (PH).
Studies by Bernard Lechner of RCA in the US and Richard Jackson at Philips
Laboratories in Europe determined that actual viewing distance for standard
definition TV is around 10 feet (3 meters).8 The screen size that corresponds to
7.15 Picture Heights at this distance is 28 inches diagonal. This roughly matches
the larger CRT sizes of the standard definition era.
Movie theater design has been influenced by similar calculations. In the 1940s,
the Society of Motion-Picture Engineers (SMPE) made a recommendation called
the 2-6 rule.9 It proposed that theater auditoriums be designed with the nearest
seats at two times picture width and the farthest at six times picture width. Using
the Academy Aperture screen shape of the time, that translates to a minimum
viewing distance of 2.67 Picture Heights.
When high definition television was first proposed, the design goal was to equal
the performance of movie theaters. This dictated an increase in TV resolution
sufficient to create the illusion of a seamless image at roughly three Picture
Heights.10 (The actual figure is 3.16 Picture Heights.) This similarity to the 2.67
specification of old movie theaters is not a coincidence. It is by design.
Since the 1940s, just about everything in movie theaters has been transformed,
including auditorium design. Through the 1990s, new theater designs moved to
progressively wider-angle projection lenses, which suggests that seats became
progressively closer to the screen.11 Today in many stadium seating auditoriums,
the back of the room is three Picture Heights, a distance formerly among the
closest seats in the house. The closest seats are less than one Picture Height
from the screen.
1
Viewing distance and viewing angle.
Any specified viewing distance also enables us to calculate the angle of view that
the picture occupies. In the sample 298-seat auditorium, the front row is roughly
one Picture Height from the screen while the back row is roughly three Picture
Heights. The most desired seats for the most enthusiastic ticket holders are
roughly 1.5 Picture Heights from the screen. At this distance, the vertical angle
of view is 37°.
How many pixels does a viewer require?
We can multiply this vertical angle of view by the number of pixels per degree to
determine the number of vertical pixels required to produce a visibly seamless
image for a viewer with good eyesight. The "relaxed" reference of 44 pixels per
degree multiplied by 37 degrees vertical equals 1628 pixels vertical.
How does this number compare to 2K? The typical modern movie has a picture
width-to-height proportion ("aspect ratio") of 1.85:1. 2K projection
accommodates this aspect ratio picture with 1998 pixels horizontal by 1080
pixels vertical. (Different aspect ratios use different accommodations.12) The
1080 pixels of 2K projection fall 34% short of the 1628 pixels required to create a
seamless picture.
Of course, this 2K shortfall varies according to viewing distance. Sit closer and
the shortfall becomes more severe. Sit further and the shortfall will diminish,
eventually to zero. The shortfall is also linked to the reference for visual acuity.
Using 60 pixels per degree, which corresponds to recognizing the "E" on the
20/20 line of the eye chart, 2K projection can only provide half of the required
2220 pixels.13
Assuming appropriate content and a 2K projector that's in focus, the 2K shortfall
can create a problem for viewers in contemporary stadium seating theaters. At
practical viewing distances, the drawbacks of 2K presentation will be visible.
These limitations can include the visibility of individual pixels, which can
undermine the illusion of reality. Stairstep "jaggies" can add unwanted texture to
diagonal lines in the picture. And gaps between pixels can put a fine mesh of
black lines across the entire image, as if the picture were viewed through a
screen door. (And if a projectionist were to deliberately put a 2K projector out of
focus to conceal these artifacts, the picture would lose even more detail.) For
many audience members, the benefits of 4K projection will be visible.
This exaggerated view depicts the effect of stairstep "jaggies" and screen
door effect that become visible when you're sitting sufficiently close to a
digital projection.
Threshold of visibility for 2K pixels.
Even though the limitations of 2K are visible from a distance of 1.5 Picture
Heights, there still must be some distance at which 2K projection "satisfies"
viewers by providing a visibly seamless picture. At this threshold distance, 4K no
longer delivers an advantage. At the relaxed reference of 44 pixels per degree,
the threshold distance is 2.30 times the Picture Height. Viewers sitting closer
than 2.30 Picture Heights can see a benefit to 4K. Viewers sitting farther than
2.30 Picture Heights will see no benefit. If you pace off 2.30 Picture Heights in
the sample 298-seat auditorium, you'll find that audience members in only the
last four out of 13 rows are at a distance potentially satisfied by 2K projection.
Ticket holders in all the other rows, representing 69% of the audience, will not be
satisfied by 2K.
Possibly
satisfied
by 2K
Not satisfied by 2K
2.30 PH
Using the relaxed reference of 44 pixels per degree, 2K projection falls
short for 69% of audience members in this auditorium.
Here again, our conclusion is inextricably linked to the reference for visual acuity.
If we use the more stringent reference of 60 pixels per degreethe standard
invoked for decades in the design of motion imaging systemsthen 2K fares
considerably worse. The distance at which the 4K advantage can no longer be
seen increases to 3.16 Picture Heights. (This is the same threshold distance as
HDTV, which provides the same 1080 vertical pixels as 2K.) In the theater, this
is beyond the back wall of the auditorium. Using this reference, 100% of
audience members with good vision will be dissatisfied by 2K.
Not satisfied by 2K
3.16 PH
Using the more stringent reference of 60 pixels per degree, no audience
members will be satisfied by 2K projection.
Similar results apply to a smaller, 104-seat stadium seating auditorium.
Seeing the 4K difference for yourself.
It is possible to simulate the difference between 2K and 4K projection. The
following page provides side-by-side images14 for your evaluation. View a color
printout of this page from 8 feet, 7 inches (2.6 meters) to simulate first row seats
at 0.86 Picture Heights. From close viewing, you can easily see the difference
between the two images, especially in the windows and archways. As you would
expect, the further back you move, the less distinct the differences become.
To Simulate View from
(feet)
View from
(meters)
Digital cinema from 0.86 Picture Heights 8 feet 7 inches 2.6 meters
Digital cinema from 1.0 Picture Height 10 feet 3.0 meters
Digital cinema from 2.0 Picture Heights 20 feet 6.0 meters
Digital cinema from 3.0 Picture Heights 30 feet 9.0 meters
Of course, this demonstration is only a rough approximation of what happens in a
darkened theater.
4K projection and the 4K content pipeline.
Where are the 4K movies? As of August 2008, no digital cinematography system
can fully exploit the advantages of 4K projection. In the short run, the 4K
difference is most clearly evident with still images. However 4K content is
coming soon.
For example, digital cameras designated "4K" have already been used to shoot
features including Steven Soderbergh's "Che" (Red One camera) and Levar
Burton's "Reach for Me" (Dalsa Origin camera). While these cameras achieve
higher than HD resolution, at least one of their manufacturers has acknowledged
that their camera uses a Bayer color filter and actually achieves less than 4K
resolutioncloser to 3K. Several camera companies are now racing to introduce
the first digital cinema cameras to attain true 4K resolution.
The recent history of digital cinema leads us to expect true 4K movies soon.
After all, digital cinema production technology gets more sophisticated every day.
Before "Star Wars: Episode II, Attack of the Clones," digital cinematography was
an unproven concept. Today it is commonplace. Before "O Brother, Where Art
Thou?" the Digital Intermediate (DI) was unknown. Today the DI is standard
practice. And in just a few short years, digital cinematography has made heroic
strides in resolution, color and contrast handling. Given the unceasing progress
of digital technology, it is inevitable that true 4K productions will become common
early in the operating life of 2K digital cinema projectors.
At the studios, both Sony Pictures Entertainment and Warner Brothers have
been vocal in their support of 4K distribution. To see what studio executives are
saying about 4K, please download the newsletter at
http://pro.sony.com/bbsccms/assets/f...er/4K_DCinema_
5.pdf.
Toward more immersive entertainment.
Until the 1950s, cinema was overwhelmingly in black-and-white, with
monophonic sound and the squarish 1.333:1 aspect ratio. The advent of
television forced the cinema to adopt more immersive modes of presentation,
including color, widescreen "scope" pictures, stereo sound, and eventually digital
surround sound.
One by one, each of these cinema advances has been matched by home
entertainment. Television adopted color (starting in the 1950s), stereo sound
(1980s), widescreen presentation and digital surround sound (1990s). Today,
increasingly affordable 1080p high definition televisions challenge the cinema
with resolution that is in some ways comparable to 35mm film and is almost
exactly equal to 2K resolution. With 1.85 aspect ratio content, 2K has exactly the
same number of vertical pixels as HDTV, and just 4.1% more horizontal pixels.
Simply stated, 2K is insufficient to position the cinema as clearly superior to
HDTV. Visible pixels, jagged outlines and screen door effect won't work when
your audiences can enjoy superb pictures of nearly identical resolution at home.
And whatever value 2K may have in the short term, it will certainly be undercut
as the studios increasingly roll out 4K distribution. Investment in 2K digital
cinema projection is in effect a bet against the relentless advance of digital
technology.
1080p Home HDTV
1920 H x 1080 V
2,073,600 pixels
2K Projection
1.85 Aspect Ratio
1998 H x 1080 V
2,157,840 pixels
When projecting 1.85 aspect ratio content, 2K projection provides only
4.1% more pixels than HDTV showing 1.78 aspect ratio content.
Like color, widescreen, stereo and surround sound before it, 4K is another giant
advantage in the ongoing competition between the theater experience and
electronic entertainment in the home. 4K projection is scalable, accommodating
4K, 2K, HD and other digital content. In fact, the smaller pixels of 4K projection
and contemporary signal processing actually improve the presentation of 2K
material.15 Finally, 4K is flexible, supporting both 2D and 3D presentation. The
choice between 2K and 4K is a choice between limiting yourself with a short-term
solution and maximizing your return for years to come.
To find out more and to see 4K and 2K head-to-head in a suitable environment,
register online today at www.sony.com/digitalcinema.
Glossary.
20/20. The Snellen Fraction that represents standard visual acuity. 20/20 vision
corresponds to 60 pixels per degree and 30 line pairs per degree.
2-6 rule. A 1940s-vintage engineering recommendation for movie theaters that
specified a viewing distance of 2 to 6 times the picture width, equal to 2.67 to 8
times the picture height.
2K. A Digital Cinema distribution and projection system that uses an image
container of 2048 pixels horizontal by 1080 pixels vertical. 2K projectors can
show either 2K or 4K content.
4K. A Digital Cinema distribution and projection system that uses an image
container of 4096 pixels horizontal by 2160 pixels vertical. 4K projectors can
show either 2K or 4K content.
Arcminute. A measure of angle equal to 1/60 degree.
Aspect ratio. The ratio of picture width to picture height. In movies, this can
vary from title to title.
Aspect ratio accommodation. The method of exhibiting movies of varying
aspect ratios on a digital projector with a fixed aspect ratio. For example, while
2K projectors have 2048 x 1080 pixels, movies with an aspect ratio of 1.85 are
accommodated at 1998 x 1080 pixels.
DCI. Digital Cinema Initiatives, LLC, the body responsible for recommending
technical specifications for Digital Cinema distribution, encryption and projection.
The DCI specification supports both 2K and 4K distribution and projection.
Fovea. The visual center of the retina, where the eye is most sensitive to detail.
HDTV. High Definition Television, a family of TV broadcast and display formats
up to a maximum of 1920 pixels horizontal by 1080 pixels vertical.
Jaggies. In digital projection, stairstep effects that are especially visible at the
diagonal edges of on-screen objects. Can be annoying for audience members
sitting close to the screen.
Line pairs. Adjacent black and white lines of a given thickness, used in
resolution test charts. Visual acuity can be stated in line pairs per degree.
K. In computer-speak, two to the tenth power or 1,024. In digital film scanning,
the width of the image is described as 2K (2048) or 4K (4096) pixels.
Picture height. A measure of relative viewing distance that enables
comparison among screens of different sizes.
Pixel. Short for "picture element," the smallest independently described area of
a digital image. Pixels can be physical, as on a camera image sensor or
projector. They can also be logical, as data in a digital image file.
Screen door effect. In digital projection, a grid of black vertical and horizontal
lines between pixels that can be annoying for audience members sitting close to
the screen.
SDTV. Standard Definition Television. In the United States, this corresponds to
a digital image of 720 pixels horizontal by 480 pixels vertical.
Snellen Fraction. The eye doctor's measure of visual acuity. Standard acuity is
20/20 in the United States, referenced to feet. Internationally, it's 6/6, referenced
to meters.
Stadium seating. The modern auditorium design that pushes the audience far
closer to the screen than the classic 2-6 rule.
Viewing angle. The angle occupied by a given screen at a given viewing
location. Viewing angles increase as the audience sits closer.
Viewing distance. The distance from the screen to a given viewer. To simplify
comparisons of different screen sizes, this is often stated in terms of Picture
Height (PH).
Visual acuity. Sensitivity of the eye to detail. While most commonly stated as a
Snellen Fraction, such as 20/20, it can also be expressed in pixels per degree or
line pairs per degree.
