Physics the camera

By Nirmal Roshan
&
Deepak
Chakravarti

Camera Obscura
 The camera obscura (Lat. dark chamber) was an optical device
used in drawing, and one of the ancestral threads leading to the
invention of photography. In English, today's photographic
devices are still known as "cameras"

 The principle of the camera obscura can be demonstrated with a
rudimentary type, just a box (which may be room-sized, or even
hangar sized) with a hole in one side. Light from only one part of
a scene will pass through the hole and strike a specific part of
the back wall. The projection is made on paper on which an artist
can then copy the image. The advantage of this technique is that
the perspective is accurate, thus greatly increasing the realism
of the image

 In camera terms, the light converges into the room through the hole
transmitting with it the object(s) facing it. The object will appear in
full colour but upside down on the projecting screen/wall opposite the
hole inside the dark room. The explanation is that light travels in a
straight line and when some of the rays reflected from a bright
subject pass through the small hole in thin material they do not
scatter but cross and reform as an upside down image on a flat white
surface held parallel to the hole

Pinhole Camera
 A pinhole camera is a camera in which the lens is replaced by an
extremely small hole, pierced in very thin material. Light from a
scene passes through this single point, producing a more-or-less
sharp image on the rear of a light-proof box. The image is upside-
down, as in a conventional camera with a lens

 do - is the distance of the object (from the pinhole)
di - is the distance of the image (from the pinhole)
ho - is the height of the object, hi - is the height of the
image

 The smaller the hole, the sharper the image, but the longer the
exposure required. Optimally, the size of the pinhole, or aperture,
should be 1/100 or less of the distance between it and the screen
 A pinhole camera's shutter is usually manually operated
because of the lengthy exposure times, and consists of a flap
of some light-proof material to cover and uncover the pinhole.
Typical exposures range from 5 seconds to hours and
sometimes days

Box Cameras
 The box camera is, with the exception of the pin hole camera,
a camera in its simplest form. The classic box camera is
shaped more or less like a box

 A box camera has a simple optical system, often only in the form
of a simple meniscus lens. It usually lacks a focusing system (fix-
focus) as well as control of aperture and shutter speeds. This
makes it suitable for daylight photography only

 The box cameras are the oldest class of photographic
cameras. The first camera ever used for making persistent
photographic images was the big wooden box camera used
for experimental photography in the mid-1820s

 From the beginning amateurs were participating in the
photography business, at least as customers for photographic
material. But traveling was expensive, and camera equipment
was heavy, so that a camera was even not in the luggage of
many rich travelers. Circumstances had changed at the end of
the 19th century. Dry plates, roll film, drugstores with
darkrooms to rent, material and infrastructure were given to
support a wider spreading of amateur photography

 The Kodak introduced in 1888, the first commercially successful
box camera for roll film -- the advertising slogan being ‘You
press the button - we do the rest’
 The Kodak Brownie, a long lasting series of classical box
cameras using roll film

 A camera where the photographer sees exactly the same image
that is exposed to the film and can adjust everything by turning
dials and clicking buttons. Since it doesn't need any electricity to
take a picture, a manual SLR camera provides an excellent
illustration of the fundamental processes of photography
‘SLR’ – Single lens reflex
means that the same lens is used for viewing and taking pictures

 A still film camera is made of three basic elements: an optical element
(the lens), a chemical element (the film) and a mechanical element (the
camera body itself). As we'll see, the only trick to photography is
calibrating and combining these elements in such a way that they
record a crisp, recognizable image

 Most point-and-shoot cameras are fully automatic.
Conceptually, automatic cameras are pretty much the same as
fully manual models, but everything is controlled by a central
microprocessor instead of the user

 The central microprocessor receives information from the
autofocus system and the light meter. Then it activates
several small motors, which adjust the lens and open and
close the aperture. In modern cameras, this a pretty
advanced computer system

 In 1981, Sony unveiled the first consumer camera to use a
charge-coupled device for imaging, eliminating the need for
film: the Sony Mavica. While the Mavica saved images to disk,
the images were displayed on television, and the camera was
not fully digital

 The Kodak Professional Digital Camera System (unofficially named
the DCS 100) was the first DSLR camera. It was mounted on a Nikon
F3 body and released by Kodak in May of 1991

 The image sensor employed by most digital cameras is a charge
coupled device (CCD). Some cameras use complementary
metal oxide semiconductor (CMOS) technology instead. Both
CCD and CMOS image sensors convert light into electrons
CMOSCCD

 A CCD transports the charge across the chip and reads it at one corner
of the array. An analog-to-digital converter (ADC) then turns each
pixel's value into a digital value by measuring the amount of charge at
each photosite and converting that measurement to binary form
 CMOS devices use several transistors at each pixel to amplify and move
the charge using more traditional wires. The CMOS signal is digital, so it
needs no ADC
 Once the sensor converts the light into electrons, it reads the value
(accumulated charge) of each cell in the image. This is where the
differences between the two main sensor types kick in:

 CCD sensors create high-quality, low-noise images. CMOS sensors are
generally more susceptible to noise
 Because each pixel on a CMOS sensor has several transistors located
next to it, the light sensitivity of a CMOS chip is lower. Many of the
photons hit the transistors instead of the photodiode
 CMOS sensors traditionally consume little power. CCDs, on the other
hand, use a process that consumes lots of power. CCDs consume as
much as 100 times more power than an equivalent CMOS sensor
 CCD sensors have been mass produced for a longer period of time, so
they are more mature. They tend to have higher quality pixels, and more
of them
 Differences between the two types of sensors lead to a number of
pros and cons

 The amount of detail that the camera can capture is called the
resolution, and it is measured in pixels. The more pixels a camera
has, the more detail it can capture and the pictures can be larger
without becoming blurry or ‘grainy’

 256x256 - Found on very cheap cameras, this resolution is so low that
the picture quality is almost always unacceptable. This is 65,000 total
pixels
 640x480 - This is the low end on most "real" cameras. This resolution is
ideal for e-mailing pictures or posting pictures on a Web site
 1216x912 - This is a "megapixel" image size -- 1,109,000 total pixels --
good for printing pictures
 1600x1200 - With almost 2 million total pixels, this is "high resolution."
You can print a 4x5 inch print taken at this resolution with the same
quality that you would get from a photo lab
 2240x1680 - Found on 4 megapixel cameras -- the current standard --
this allows even larger printed photos, with good quality prints upto
5.25x8 inches
 4064x2704 - A top-of-the-line digital camera with 11.1 megapixels takes
pictures at this resolution. At this setting, you can create 13.5x9 inch
prints with no loss of picture quality

The largest are the ones used in "medium format" cameras,
typically via a "digital back" which can be used as an
alternative to a film back. Because of the manufacturing
costs of these large sensors the price of these cameras is
typically over Rs. 10,00,000
 Image sensors used in DSLRs come in a range of sizes

With the exception of medium format DSLRs, the largest
sensors are referred to as "full-frame", and are the same size
as 35 mm film; these sensors are used in quite expensive DSLRs
such as the Canon EOS-1Ds Mark III, the Canon EOS 5D, the
Nikon D700, and the Nikon D3

Most modern DSLRs use a smaller sensor commonly referred to as
APS-C sized, that is, approximately 22 mm × 15 mm, or about 40% of
the area of a full-frame sensor
Other sensor sizes found in DSLRs include the ‘Four Thirds System’
sensor at 26% of full frame, APS-H sensors at around 61% of full
frame, and the ‘Foveon X3’ sensor at 33% of full frame

The sensors used in current DSLRs are much larger than the
sensors found in digicam-style cameras, most of which use
sensors known as 1/2.5", whose area is only 3% of a full frame
sensor. Even high-end digicams such as the Canon PowerShot G9
or the Nikon CoolPix P5000 use sensors that are approximately
5% and 4% of the area of a full frame sensor, respectively

There is a connection between sensor size and image quality; in
general, a larger sensor provides lower noise, higher sensitivity,
and increased latitude and dynamic range

According to the U.S. survey results, more than two-thirds (68
percent) of professional photographers prefer the results of film to
those of digital for certain applications including:
 Film’s superiority in capturing more information on medium and
large format films (48 percent)
 Capturing shadow and highlighting details (45 percent)
 The wide exposure latitude of film (42 percent)
 According to a survey made by Kodak in 2007, 75 percent of
professional photographers say they will continue to use
film, even though some embrace digital

Digital point-and-shoot cameras have become widespread
consumer products, outselling film cameras, and including
new features such as video and audio recording

Kodak announced in January 2004 that it would no longer
sell reloadable 35 mm cameras in western Europe, Canada
and the United States after the end of that year

In January 2006, Nikon followed suit and announced that they
will stop the production of all but two models of their film
cameras: the low-end Nikon FM10, and the high-end Nikon F6

On May 25, 2006, Canon announced they will stop
developing new film SLR cameras

Physics the camera

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