Contents

Search in book...
Toggle Font Controls
Create new playlist

Name your new playlist

Playlist description (optional)
Sign In

Email address

Password

Forgot Password?

or

Continue with Facebook

Continue with Google
Sign Up

Full Name

Email address

Confirm Email Address

Password

or

Continue with Facebook

Continue with Google

Previous Chapter

Contents

Editors’ Acknowledgements

Author Biographies

1. Introduction to the imaging process

The imaging process

Control of image shape

Tone and contrast

The origins of photography

Early experiments

Towards the development process – the Daguerreotype

The negative–positive process

Modern materials

Photographic imaging today

Characteristics of photographic materials

Capturing colour

Digital imaging

Early digital images

The CMOS sensor

Colour digital capture

Other digital devices

Digital image representation

Spatial resolution

Colour representation

File size and file formats

Evaluating image quality

2. Light theory

A brief history of light theory

Wave–particle duality

The nature of light

Radiometry and photometry

Radiometric definitions

Photometric definitions

Simple harmonic motion

Principle of superposition

Light intensity

Refraction and dispersion

Diffraction of a circular aperture and a single slit

Rayleigh criterion

The electromagnetic spectrum

Black-body radiation

Wien’s Displacement Law

The photoelectric effect

Bohr model of the atom

The emission of electromagnetic radiation in atoms

3. Photographic light sources

Characteristics of light sources

Spectral quality

Spectral power distribution curve

Colour temperature

Colour rendering

Percentage content of primary hues

Measurement and control of colour temperature

The mired scale

Illumination laws

Reflectors and luminaires

Constancy of output

Tungsten filament lamps

Tungsten–halogen lamps

Fluorescent lamps

Metal-halide lamps

Pulsed xenon lamps

Expendable flashbulbs

Electronic flash

Flash circuitry

Flash output and power

Flash duration and exposure

Automatic flash exposure

Integral flash units

Red-eye avoidance

Light-emitting diodes

4. The human visual system

The physical structure of the human eye

Crystalline lens

Vitreous cavity and vitreous humour

Retina and choroid

Structure of the retina

‘Non-imaging’ cell layers

Receptive fields

Dark adaptation

Elementary colour vision

Young–Helmholtz theory of colour vision

Opponent theory of colour vision

Colour anomalous vision

Movement and Focusing

Focusing and correction of eyesight

The visual pathway

Binocular vision

Performance of the eye

Luminance discrimination

Contrast sensitivity function

5. Introduction to colour science

The physics of colour

Colour terminology

The colour of objects

Spectral absorptance, reflectance and transmittance

CIE standard illuminating and viewing geometries

CIE standard illuminants and sources

Models of colour vision

The basics of colorimetry

Colour matching functions and the CIE standard observers

Calculating tristimulus values from spectral data

Chromaticity diagrams

CIE uniform colour spaces and colour differences

Metamerism and types of metameric matches

The appearance of colours

Visual adaptation and related mechanisms

Other colour appearance phenomena

An introduction to CATs and CAMs

A generalized CAT

Colour appearance models (CAMs)

Colour reproduction

Objectives of colour reproduction

Instruments used in colour measurement

Viewing conditions

6. Photographic and geometrical optics

Photographic optics

Optical materials

Geometrical optics

Cardinal planes

Image magnification

Optical calculations

Focusing movements

Depth of field and depth of focus

The photometry of image formation

Stops and pupils

Image luminance and illumination

Image illuminance

Exposure compensation for close-up photography

Anti-reflection coatings

Types of coating

7. Images and image formation

Sinusoidal waves

Images and sine waves

Imaging sinusoidal patterns

Fourier theory of image formation

Linear, spatially invariant systems

Spread functions

The point spread function (PSF)

The line spread function (LSF)

The edge spread function (ESF)

The imaging equation (from input to output)

The imaging equation in one dimension

The modulation transfer function (MTF)

Special Fourier transform pairs

The rectangular function

The Dirac delta function

Properties of δ(x)

Importance of δ(x)

The Gaussian function

The modulation transfer function revisited

Cascading of MTFs

Convolution revisited

A geometric interpretation of convolution

The convolution theorem

Discrete transforms and sampling

Undersampling a cosine wave

The Dirac comb (the sampling function)

The process of sampling

The MTF for a CCD imaging array

8. Sensitometry

Density and other relevant measures

Effect of light scatter in a negative

Callier coefficient

Density in practice

The Characteristic (H and D) curve

Main regions of the negative characteristic curve

Variation of the characteristic curve with the material

Gamma–time curve

Variation of gamma with wavelength

Placing the subject on the characteristic curve

Effect of variation of exposure of the negative

Average gradient and Ḡ

Effect of variation in development on the negative

Exposure latitude

The response curve of a photographic paper

Exposure range of a paper

Variation of the print characteristic curve with the type of emulsion

Variation of the print characteristic curve with development

Requirements in a print

Reciprocity law failure

Practical effects of reciprocity failure

Intermittency effect

Microdensitometers

Colour densitometers

9. Image sensors

Materials and detection of light

Conductors, insulators and semiconductors

Photoemission and photoabsorption

CCD and CMOS sensors

CCD and CMOS image readout

Amplification and analogue-to-digital conversion

Scanning methods

Imaging performance

Performance trade-offs

Microlens arrays

Exposure control

Sensor imperfections

Generating colour

10. Camera lenses

Lens aberrations

Axial chromatic aberration

Lateral chromatic aberration

Spherical aberration

Curvature of field

Curvilinear distortion

Lens aperture and performance

Photographic lenses

Photographic lens types

Compound lenses

Development of the photographic lens

Simple lenses and achromats

The Petzval lens

Symmetrical doublets

Double-Gauss lenses

Modern camera lenses

Wide-angle lenses

Symmetrical-derivative lenses

Retrofocus lenses

Fish-eye lenses

Long-focus lenses

Long-focus designs

Telephoto lenses

Catadioptric lenses (‘mirror lenses’)

Zoom and varifocal lenses

Zoom lenses for compact and digital cameras

Optical attachments

Afocal converter lenses

Close-up (supplementary) lenses

Other attachments

Optical filters

Absorption filters

UV and IR filters

Neutral-density filters

Polarizing filters

11. Photographic camera systems

Compact cameras

Rangefinder cameras

Twin-lens reflex (TLR) cameras

Single-lens reflex (SLR) cameras

Technical cameras

Special-purpose cameras

Cameras for self-developing materials

Underwater cameras

Ultrawide-angle cameras

Panoramic cameras

Automatic cameras

Analogue systems

Digital control

Camera features

Shutter systems

Flash synchronization

The iris diaphragm

Viewfinder systems

Focusing systems

Autofocus systems

Exposure metering systems

Automatic exposure

Programmed exposure modes

Segmented photocell systems

Camera shake and image stabilization

Camera movements

12. Exposure and image control

Camera exposure

Exposure relationships and logarithms

Relative aperture

Subject luminance ratio

Dynamic range of sensors

Optimum exposure and the transfer function

Exposure meters

Hand-held exposure meters

Acceptance angle

Exposure values

Exposure factors

Reciprocity law failure

Types of light measurement

Incident light measurement

Reflected light measurement

In-camera metering modes

Partial area metering

Centre-weighted average metering

Matrix or multi-zone metering

Electronic flash exposure

Reflected light measurement techniques

Measurement of total scene luminance

Measuring a middle grey surface (key tone)

Measurement of luminance of the darkest shadow

Measurement of luminance of the lightest highlight

Averaging values

Exposure techniques and digital cameras

Using the image histogram

‘Exposing to the right’

The zone system

The zone system and digital cameras

High-dynamic-range (HDR) imaging

13. Image formation and the photographic process

Latent image formation

Spectral sensitivity of photographic materials

Response of photographic materials to short-wave radiation

Response of photographic materials to visible radiation

Spectral sensitization

Orthochromatic materials

Panchromatic materials

Extended sensitivity materials

Infrared materials

Other uses of dye sensitization

Structure of photographic materials

Production of light-sensitive materials and sensors

Coating the photographic emulsion

Sizes and formats of photographic materials

Speed of photographic materials

Speed systems and standards

Characteristics of photographic materials

Graininess and granularity

Sharpness and acutance

Chemistry of the photographic process

Developers and development

Composition of a developing solution

Developing agents

Restrainers (anti-foggants)

Miscellaneous additions to developers

Superadditivity (Synergesis)

Development time

14. Digital cameras and scanners

Digital still cameras

Digital still camera architecture

Shutter systems

Dynamic range in digital cameras

Three-sensor cameras

Sequential colour cameras

Colour filter array (CFA) cameras

The Super CCD™

The Foveon™ sensor

Rendered versus unrendered camera processing

Exposure determination and auto-exposure

Autofocus control

Analogue processing

Digital processing

Colour demosaicing

Setting white balance

Digital zoom, resizing and cropping

Noise reduction

Tone/colour rendering

Compact digital cameras

Bridge digital cameras

Digital single-lens reflex (DSLR) cameras

Digital cameras and camera backs for medium and large format

Specialist digital cameras

Types of scanners

Flatbed scanners

Flextight scanners

Multi-spectral scanners

Scanner characteristics

Sampling and resolution

Scanner drivers

15. Displays

Cathode ray tube (CRT) displays

Liquid crystal displays (LCDs)

Other display technologies

Plasma display panels (PDPs)

Organic light-emitting displays (OLEDs)

Flexible displays

Characteristics of displays

Refresh rate and response time

Display artefacts

Effect of viewing conditions

16. Digital printing and materials

Printing technologies

Inkjet printers

Electrophotographic printers

Printing media and their properties

Paper for inkjet printing

Inks for inkjet printing

Toner materials

Colour, resolution and output

Half-toning and dithering

Relief printing

Planographic printing (or lithography)

Recess printing

Through printing

17. Digital image file formats

Raster and vector graphics

Bit-depth support and colour encoding

Compression methods

Standardization of the format

Metadata and Exif

Colour management

Additional features

Tagged image file format (TIFF)

Joint Photographic Experts Group (JPEG)

Joint Photographic Experts Group 2000 (JPEG 2000)

Digital negative (DNG)

Graphics interchange format (GIF)

Portable network graphics (PNG)

Photoshop document (PSD)

Postscript (PS) and encapsulated postscript (EPS)

Portable document format (PDF)

18. Image storage and archiving

Life expectancy of traditional photographic media

Processing conditions

Storage conditions

Atmospheric gases

Life expectancy of digital prints

Printing technologies and media

Permanence factors and test for digital prints

Digital image storage and longevity

Magnetic storage

Optical disc storage

Other digital image archiving issues

19. Introduction to image quality and system performance

Subjective and objective image quality

Image quality assessment

Basic image quality attributes (or dimensions)

The image quality circle

Further image quality attributes

Digital image artefacts

Distortion, fidelity and quality

Image distortion

The use of a reference image

Test charts and test scenes

Image psychophysics

Psychometric scales

The psychometric function

Scaling methods

Scene dependency in image quality

Choice of test scenes

Image quality metrics and models

20. Speed and sensitivity

Sensitivity of imaging systems

Spectral sensitivity of digital cameras

Measurement of the spectral sensitivity of digital cameras

Determination of the colour sensitivity of an unknown photographic emulsion

Wedge spectrograms

Uses of wedge spectrograms

Speed of imaging systems

Methods of expressing speed

Threshold systems

Minimum useful gradient

Fractional gradient

Speed systems and standards

ISO speed ratings for colour silver-based materials

Colour negative film

Colour reversal film

Speed of digital systems

Speed based on saturation (S_sat)

Speed based on noise (S_noise)

Standard output sensitivity (SOS)

Recommended exposure index (REI)

Digital camera ISO settings

Typical sensitivities of film and CCD devices and speed ratings in practice

21. Tone reproduction

Theory of tone reproduction

Transfer functions and gamma

Overall transfer function and overall gamma

Subjective tone reproduction, optimum gamma and viewing conditions

Quadrant diagram

Tone reproduction of imaging devices and image encoding systems

CRT display transfer function

Liquid crystal display (LCD) transfer function

Measuring display transfer functions

Transfer functions of digital acquisition devices

Measuring acquisition device transfer functions

Image encoding: sRGB, Adobe RGB and JPEG transfer functions

Transfer functions of printers

Other measures related to tone and contrast

Dynamic range and contrast ratio

Contrast in uniform areas, test targets and images

Non-linear quantization, bit-depth requirements and gamma correction

22. Photographic colour reproduction

Complementary pairs of colours

Colour photographic processes

Additive colour photography

Subtractive processes

Integral tripacks

Formation of subtractive image dyes

Colour sensitometry

Negative–positive colour

Reversal colour

Colour photographic materials

Location of colour formers

Colour processing

Reversal process

Negative–positive process

Prints from transparencies

Enhancement of colour reproduction

Colorimetry of photographic images

23. Digital colour reproduction

Colour space and colour encoding

Classification of colour spaces

RGB (red, green, blue)

CMY(K) (cyan, magenta, yellow, black)

HSL (hue, saturation, lightness) – and similar

YCC (luminance, chrominance 1, chrominance 2) – and similar

CIE colour spaces

Colorimetric colour spaces

Colour appearance spaces

Device dependent colour spaces

Sensor colour encoding

Scene-referred colour encoding

Output-referred colour encoding

Original-referred colour encoding

Standard colour space and colour space encodings

sRGB (standard RGB) and sRGB-related colour space encodings

sYCC and sYCC-related

ROMM RGB and RIMM RGB

Device colour characterization

Physical models

Numerical models

Look-up tables with interpolation

Evaluation of the characterization model

Characterization of displays

Characterization of digital input devices

Gamut mapping aims

Gamut mapping techniques

24. Noise, sharpness, resolution and information

Causes of noise in an image

Photographic noise

Factors affecting the graininess of prints

Factors affecting negative granularity

Variation of granularity with density

Quantifying image noise

Estimating σ²

The autocorrelation function

The noise power spectrum

Relationships between noise measures

Practical considerations for the autocorrelation function and the noise power spectrum

Using the autocorrelation function

Direct Fourier transformation of noise samples

Signal-to-noise ratio

Electronic system noise

Resolution, sharpness and MTF

Resolving power of photographic systems

Measuring modulation transfer functions

Wave recording – sine-wave method

Wave recording – square-wave methods

Edge input method

Slanted edge method

Resolving power and MTF for optical systems

Sharpness, MTF and image quality

Detective quantum efficiency (DQE)

General considerations

DQE for the photographic process

DQE for a CCD or CMOS imaging array

DQE and signal-to-noise ratio

Information theory

Information capacity of images

25. Digital image workflow

Imaging chains and image workflow

Principles guiding effective workflow

Workflow approach

Resolution and the digital imaging chain

Interpolation methods and associated artefacts

Interpolation and image workflow

Calculating required resolution for image output

Bit depth: 8-bit versus 16-bit imaging

Colour management

Colour workflow

Image acquisition

RAW capture and workflow

Image archiving

Image optimization workflow

Workflow examples

1. Commercial photography

2. Forensic imaging

3. Medical imaging

Acknowledgements

26. Colour management systems

Colour management tasks

Closed-loop versus open-loop colour management

The International Color Consortium (ICC)

ICC colour management architecture

The profile connection space (PCS)

Rendering intents

The ICC perceptual intent reference medium and reference viewing conditions

Profile processing models

Profile structure

Structure of device profiles

Structure of colour space conversion profiles

Creating custom device profiles

Display profiles

Scanner profiling

Digital camera profiling

Using camera profiles

Output profiles

Colour management workflow

Colour rendering options

Early-binding versus late-binding workflow

RGB and CMYK workflows

Using an intermediate colour space

Proofing and soft-proofing images

27. Spatial image processing

Structure of the digital image

Implementation of spatial domain processes

Linear systems theory

Discrete convolution

Point processing operations: intensity transformations

Brightness and contrast changes using linear transformation functions

Piecewise linear functions

Image thresholding and quantization

Power-law transformations: gamma correction

Point processing: multiple image operations

Enhancement using arithmetic operations

Enhancement using logic operations

Point processing: statistical operations

The image histogram

Probability density function and probability distribution function

Histogram slide and stretch

Histogram equalization

Point processing: geometric transformations

Neighbourhood processing: spatial filtering techniques

Linear filtering

Properties of linear filters

Types of linear filters and their applications

Smoothing spatial filters

Edge detection and sharpening spatial filters

Non-linear spatial filtering

Minimum and maximum filters

28. Digital image processing in the frequency domain

Fourier series and transform revisited

Fast Fourier transform (FFT)

Imaging equation revisited

Linear spatial filtering (convolution)

Frequency-domain filtering

Low-pass filtering

High-pass filtering

High-boost filter

Band-pass and band-Stop filters

Image restoration

Inverse filtering

Optimal or Wiener filtering

Maximum entropy reconstruction

Interactive restoration

Extended depth of field (EDOF)

Wavelet transform

Discrete wavelet transform

29. Image compression

Uncompressed image file sizes

Image data and information

Basis of compression

Types of redundancy

Measuring compression rate

Scene dependency and compression

Information theory

Entropy and image structure

Shannon’s theorem

Image compression models

Lossless compression

Lossless compression methods

Reducing spatial redundancy

Reducing coding redundancy: variable-length coding

Lossy compression

Evaluating lossy compression

Distortion metrics

Alternative assessment methods

Lossy compression methods

Lossy compression standards

Joint Photographic Experts Group (JPEG) standard

JPEG 2000 standard

..................Content has been hidden....................

You can't read the all page of ebook, please click here login for view all page.