Information is anything that increases our image of knowledge of a system or process (MacKay), for instance, a type of arrangement or regularity which can be recognized in the environment. The letters on a page show a certain regularity and the message involved is recognized by the sequence in which the letters have been printed. For instance, information content is implemented in the order in which the letters appear on paper, and a limited quantity of information is conveyed. We can also say information is anything which reduces uncertainty of the source sending this information. We call this type semantic information and it is language related. If the same letters appear completely at random, all semantic information is lost and interpretation is no longer possible. The amount of semantic information has become zero. It is also said the left redundancy is zero.

To illustrate the concept of information redundancy in a language consider the following sentence: ‘N t mrng t bkr bks brwn brd’. Although characters are missing you still can read this sentence; in other words in most sentences or words redundancy is present.

However, no quantitative measure for semantic information is known so far. This example explains why it is said that information always involves a certain amount of regularity. Put in a reverse way, every regularity contains a limited quantity of information. Here order and disorder or information and chaos are each other’s opposites.

A source produces symbols from an alphabet with 26 different characters with the following probabilities: p = 1/8 for 1 character; p = 1/16 for 8 characters; p= 1/32 for 9 characters; p=1/64 for 4 characters; p= 1/128 for 4 characters. Then the selective information is

The maximum amount of selective information is found for a symmetric distribution, hence H_max = log 26 = 4.700 bit/char. Then the redundancy, Red. = (H_max−H)/H_max = (4.7−4.375)/4.7 = 0.0691. Note that when H = H_max then Red. = 0!

When a certain event occurs a limited amount of information is received. The interrelationship between information and chaos was first shown by Shannon, who has connected the idea of information to entropy. In accordance with the second law of thermodynamics in a closed system the entropy increases towards a maximum, which corresponds to a minimum amount of energy in that system. Hence, entropy is defined as a measure for chaos, or disorder. Information can be quantified accordingly, based on the uncertainty of possible events and their probability of occurrence. On the basis of this concept a smallest amount of selective information is defined. We will not go into further detail here, but reference is made to the relevant literature. In this respect another important definition to distinguish is the concept of knowledge. Knowledge is anything that reduces uncertainty of a system or process. It is the same concept as information. However, we can distinguish knowledge in a different respect. Firstly, we can distinguish perceptual knowledge as parametric knowledge, which is based on by whom, where and when the information is interpreted. Secondly, we can distinguish knowledge revealed from natural laws and not dependent on human interpretation, for instance Newton’s law on gravitation or Ohm’s law. If an experiment is repeated under the same conditions the same results are always found. Finally, we can distinguish knowledge known by intuition. It is the way artists know how to make something, or how sometimes an invention is born. It is just there and the explanation ‘why’ follows (sometimes) later on. A nice example is the discovery of superconductivity in 1911 by Kamerling Onnes explained in 1957 by Bardeen, Cooper and Schiefer (the BCS theory).