In photomechanical imaging, the characteristics of the image are self-evident: it includes the tonal and color information, along with a grain or dot structure. This corresponds to the most basic digital images, which were originally just a rectangle full of colored dots representing tone, color and resolution. 

As technology evolved, digital images have become far more complex. At first, this was playing catch-up with physical images. For more than a decade now, digital images have included components that extend our understanding of exactly what an image is. Here are some examples of that evolution. 

Color management

The numbers that are used to describe colors could be calculated many different ways, Color management is a system to describe exactly what is meant by a numerical value. It enables standardization of color rendering across devices that may have very different color signatures (or very different models of rendering color). 

Compression

It’s always been important to shrink digital images down as small as possible for any given use. By standardizing ways to compress and expand image data, storage and transmission bandwidth are conserved. 

Multiple images

For several decades, it’s been possible to place multiple images into a single file to create a new synthesized image. This allows images to be composited and also to be adjusted and re-edited. 

Transparency

While most digital images are rectangles, adding the capability to make some pixels transparent allows an image to take on any conceivable shape. 

Adjustment instructions

Adding color and tonal adjustment instructions to an image allows the “photo finishing” to be attached to the image itself, and for it to be readjusted non-destructively. It also allows for multiple interpretations of the same image to be “part” of a single original image. 

Masks and alpha channels

Digital images can contain other images – often a monochromatic image that can be used to mask parts of the primary image. This can be used to create a transparency of the image, or to selectively apply adjustment instructions to regions of an image, or to blend multiple images together. 

Curved and spherical models

Digital images may also be created as inherently non-flat photos that make use of curved or spherical geometry. Spherical images can be viewed in a VR environment or in a flat display that is designed to compensate for the curvature of the image. 

Motion and audio

Adding multiple sequential images to an image can create a motion image. Hybrid image files have been around for decades. Likewise, it’s been possible to attach an audio file to an image for a very long time. 

Camera raw images

Digital cameras created a new type of digital image – one that preserved camera-native information for flexible reprocessing at any point in the future. 

At this point, the nature of digital images changed radically. Entirely new image editing methods were needed, as were ways to properly store this unprocessed data. 

Depth information

Mobile phones and other computational cameras are now creating depth information as an inherent part of the image itself. This is useful for all kinds of purposes, including synthetic depth of field, Augmented Reality features, facial recognition and other visual analysis. 

Application-specific usage

Mobile imaging, raw photography and cloud workflow have created a need for even more complex image objects. This includes the need for proxy images and application-specific rendering, all as part of a single object. 

All of these above items can be integral parts of the image itself, since they inform the nature, understanding and use of the images. Many images will continue to be a simple rectangle of colored dots, but an increasing number will be more complex digital-native objects. In the next post, we will take a look at the ways that formats have evolved along with the images themselves.

One Comment

  1. Janine Wencke

    Interesting

Comments are closed.